426 54 43MB
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Mic Dou hael Ev Kay glas W ans Dav Lipso allace id T n ree by
Uni ts
1&
2
S Mat peci hem alist atic s Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cam Sen bridg e ior Ma the ma t Aus i t Cur ralian cs ricu lum / VC E
INCLUDES INTERACTIVE TEXTBOOK POWERED BY CAMBRIDGE HOTMATHS
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
477 Williamstown Road, Port Melbourne, VIC 3207, Australia Cambridge University Press is part of the University of Cambridge. It furthers the University’s mission by disseminating knowledge in the pursuit of education, learning and research at the highest international levels of excellence. www.cambridge.edu.au Information on this title: www.cambridge.org/9781107567658 © Michael Evans, Douglas Wallace, Kay Lipson, David Treeby 2016 This publication is in copyright. Subject to statutory exception and to the provisions of relevant collective licensing agreements, no reproduction of any part may take place without the written permission of Cambridge University Press. First printed 2016 Reprinted 2016 Cover designed by Loupe Design Typeset by Jane Pitkethly and Diacritech Printed in China by C&C O↵set Printing Co Ltd A Cataloguing-in-Publication entry is available from the catalogue of the National Library of Australia at www.nla.gov.au ISBN 978-1-107-56765-8 Paperback Additional resources for this publication at www.cambridge.edu.au/GO Reproduction and communication for educational purposes The Australian Copyright Act 1968 (the Act) allows a maximum of one chapter or 10% of the pages of this publication, whichever is the greater, to be reproduced and/or communicated by any educational institution for its educational purposes provided that the educational institution (or the body that administers it) has given a remuneration notice to Copyright Agency Limited (CAL) under the Act. For details of the CAL licence for educational institutions contact: Copyright Agency Limited Level 15, 233 Castlereagh Street Sydney NSW 2000 Telephone: (02) 9394 7600 Facsimile: (02) 9394 7601 Email: [email protected] Reproduction and communication for other purposes Except as permitted under the Act (for example a fair dealing for the purposes of study, research, criticism or review) no part of this publication may be reproduced, stored in a retrieval system, communicated or transmitted in any form or by any means without prior written permission. All inquiries should be made to the publisher at the address above. Cambridge University Press has no responsibility for the persistence or accuracy of URLS for external or third-party internet websites referred to in this publication, and does not guarantee that any content on such websites is, or will remain, accurate or appropriate. Information regarding prices, travel timetables and other factual information given in this work is correct at the time of first printing but Cambridge University Press does not guarantee the accuracy of such information thereafter.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Contents
Introduction
ix
Acknowledgements
xi
An overview of the Cambridge complete teacher and learning resource
xii
1
Algebra I
2
Number systems and sets
1A 1B 1C 1D 1E 1F 1G 1H 1I
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
2A 2B 2C 2D 2E 2F 2G 2H
1
Indices . . . . . . . . . . . . . . . . . . . . . . . . . . . Standard form . . . . . . . . . . . . . . . . . . . . . . . Solving linear equations and simultaneous linear equations Solving problems with linear equations . . . . . . . . . . Solving problems with simultaneous linear equations . . . Substitution and transposition of formulas . . . . . . . . . Algebraic fractions . . . . . . . . . . . . . . . . . . . . . Literal equations . . . . . . . . . . . . . . . . . . . . . . Using a CAS calculator for algebra . . . . . . . . . . . . . Review of Chapter 1 . . . . . . . . . . . . . . . . . . . .
Set notation . . . . . . . . . . Sets of numbers . . . . . . . . The modulus function . . . . Surds . . . . . . . . . . . . . Natural numbers . . . . . . . Linear Diophantine equations The Euclidean algorithm . . . Problems involving sets . . . . Review of Chapter 2 . . . . .
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2 5 8 13 17 19 22 25 28 33 39
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Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
iv
Contents
3
Variation
4
Sequences and series
5
Algebra II
6
Revision of Chapters 1–5
7
Principles of counting
3A 3B 3C 3D 3E
4A 4B 4C 4D 4E 4F
5A 5B 5C 5D 5E
6A 6B 6C
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
7A 7B 7C 7D 7E 7F 7G 7H 7I
82
Direct variation . . . Inverse variation . . Fitting data . . . . . Joint variation . . . . Part variation . . . . Review of Chapter 3
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. 83 . 87 . 91 . 98 . 101 . 104 110
Introduction to sequences . . . . . . . . . . Arithmetic sequences . . . . . . . . . . . . . Arithmetic series . . . . . . . . . . . . . . . Geometric sequences . . . . . . . . . . . . . Geometric series . . . . . . . . . . . . . . . Zeno’s paradox and infinite geometric series . Review of Chapter 4 . . . . . . . . . . . . .
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111 118 122 127 133 137 140 146
Polynomial identities . . . . . . . . . . . . . . Quadratic equations . . . . . . . . . . . . . . Applying quadratic equations to rate problems Partial fractions . . . . . . . . . . . . . . . . . Simultaneous equations . . . . . . . . . . . . Review of Chapter 5 . . . . . . . . . . . . . .
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147 151 157 162 169 173 177
Technology-free questions . . . . . . . . . . . . . . . . . . . . 177 Multiple-choice questions . . . . . . . . . . . . . . . . . . . . 179 Extended-response questions . . . . . . . . . . . . . . . . . . 182
Basic counting methods . . . . . . Factorial notation and permutations Permutations with restrictions . . . Permutations of like objects . . . . Combinations . . . . . . . . . . . . Combinations with restrictions . . . Pascal’s triangle . . . . . . . . . . . The pigeonhole principle . . . . . . The inclusion–exclusion principle . . Review of Chapter 7 . . . . . . . .
190
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191 195 201 204 207 212 216 219 223 228
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Contents
8
Number and proof
9
Geometry in the plane and proof
8A 8B 8C 8D 8E 8F
9A 9B 9C 9D 9E 9F 9G 9H 9I
Direct proof . . . . . . . Proof by contrapositive . Proof by contradiction . Equivalent statements . Disproving statements . Mathematical induction Review of Chapter 8 . .
232
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Points, lines and angles . . . Triangles and polygons . . . Congruence and proofs . . Pythagoras’ theorem . . . . Ratios . . . . . . . . . . . . An introduction to similarity Proofs involving similarity . Areas, volumes and similarity The golden ratio . . . . . . Review of Chapter 9 . . . .
10
Circle geometry
11
Revision of Chapters 7–10
12
Sampling and sampling distributions
10A 10B 10C
11A 11B 11C
12A 12B 12C 12D
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
v
Angle properties of the circle Tangents . . . . . . . . . . Chords in circles . . . . . . Review of Chapter 10 . . .
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233 238 242 246 249 251 260 265
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266 272 277 282 286 288 295 297 304 308 316
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317 322 326 329 334
Technology-free questions . . . . . . . . . . . . . . . . . . . . 334 Multiple-choice questions . . . . . . . . . . . . . . . . . . . . 337 Extended-response questions . . . . . . . . . . . . . . . . . . 342
Populations and samples . . . . . . . . . . . . . . . . The distribution of the sample proportion . . . . . . . Investigating the distribution of the sample proportion using simulation . . . . . . . . . . . . . . . . . . . . Investigating the distribution of the sample mean using simulation . . . . . . . . . . . . . . . . . . . . Review of Chapter 12 . . . . . . . . . . . . . . . . .
347
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Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
vi
Contents
13
Trigonometric ratios and applications
14
Further trigonometry
15
Graphing techniques
16
Complex numbers
13A 13B 13C 13D 13E 13F 13G 13H
14A 14B 14C 14D 14E
15A 15B 15C 15D 15E 15F 15G 15H 15I
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
16A 16B 16C 16D 16E
387
Reviewing trigonometry . . . . . . . . . . . . . . . . The sine rule . . . . . . . . . . . . . . . . . . . . . . The cosine rule . . . . . . . . . . . . . . . . . . . . . The area of a triangle . . . . . . . . . . . . . . . . . . Circle mensuration . . . . . . . . . . . . . . . . . . . Angles of elevation, angles of depression and bearings Problems in three dimensions . . . . . . . . . . . . . Angles between planes and more difficult 3D problems Review of Chapter 13 . . . . . . . . . . . . . . . . .
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388 393 397 400 403 408 412 416 421 427
Symmetry properties . . . . . . . . . . . . . . . . The tangent function . . . . . . . . . . . . . . . . Reciprocal functions and the Pythagorean identity Addition formulas and double angle formulas . . . Simplifying a cos x + b sin x . . . . . . . . . . . . . Review of Chapter 14 . . . . . . . . . . . . . . .
Reciprocal functions . . . . . . . . . . . Locus of points . . . . . . . . . . . . . . Parabolas . . . . . . . . . . . . . . . . . Ellipses . . . . . . . . . . . . . . . . . . Hyperbolas . . . . . . . . . . . . . . . . Parametric equations . . . . . . . . . . . Polar coordinates . . . . . . . . . . . . . Graphing using polar coordinates . . . . Further graphing using polar coordinates Review of Chapter 15 . . . . . . . . . .
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428 430 433 438 445 448 453
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Starting to build the complex numbers . . . . . Multiplication and division of complex numbers Argand diagrams . . . . . . . . . . . . . . . . Solving equations over the complex numbers . Polar form of a complex number . . . . . . . . Review of Chapter 16 . . . . . . . . . . . . .
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499 503 509 513 515 520
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Contents
17
Revision of Chapters 13–16
18
Matrices
19
Transformations of the plane
20
Vectors
21
Revision of Chapters 18–20
17A 17B 17C
18A 18B 18C 18D 18E
19A 19B 19C 19D 19E 19F 19G 19H
20A 20B 20C 20D 20E 20F
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
21A 21B 21C
vii
524
Technology-free questions . . . . . . . . . . . . . . . . . . . . 524 Multiple-choice questions . . . . . . . . . . . . . . . . . . . . 526 Extended-response questions . . . . . . . . . . . . . . . . . . 531 535
Matrix notation . . . . . . . . . . . . . . . . . . . . . . . Addition, subtraction and multiplication by a real number Multiplication of matrices . . . . . . . . . . . . . . . . . Identities, inverses and determinants for 2 ⇥ 2 matrices . . Solution of simultaneous equations using matrices . . . . Review of Chapter 18 . . . . . . . . . . . . . . . . . . .
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536 540 544 547 552 555 560
Linear transformations . . . . . . . . . . . . . . . Geometric transformations . . . . . . . . . . . . . Rotations and general reflections . . . . . . . . . . Composition of transformations . . . . . . . . . . Inverse transformations . . . . . . . . . . . . . . . Transformations of straight lines and other graphs Area and determinant . . . . . . . . . . . . . . . General transformations . . . . . . . . . . . . . . Review of Chapter 19 . . . . . . . . . . . . . . .
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561 565 571 574 577 581 585 590 593 598
Introduction to vectors . . . Components of vectors . . . Scalar product of vectors . . Vector projections . . . . . . Geometric proofs . . . . . . Vectors in three dimensions Review of Chapter 20 . . .
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599 607 611 614 618 621 624 629
Technology-free questions . . . . . . . . . . . . . . . . . . . . 629 Multiple-choice questions . . . . . . . . . . . . . . . . . . . . 631 Extended-response questions . . . . . . . . . . . . . . . . . . 635
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
viii
Contents
22
Kinematics
23
Statics of a particle
24
Revision of Chapters 22–23
22A 22B 22C 22D
23A 23B
24A 24B 24C
640
Position, velocity and acceleration . . . . . . . Applications of antidifferentiation to kinematics Constant acceleration . . . . . . . . . . . . . . Velocity–time graphs . . . . . . . . . . . . . . Review of Chapter 22 . . . . . . . . . . . . .
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641 646 650 653 659 666
Forces and triangle of forces . . . . . . . . . . . . . . . . . . . 667 Resolution of forces . . . . . . . . . . . . . . . . . . . . . . . . 672 Review of Chapter 23 . . . . . . . . . . . . . . . . . . . . . . 676 679
Technology-free questions . . . . . . . . . . . . . . . . . . . . 679 Multiple-choice questions . . . . . . . . . . . . . . . . . . . . 681 Extended-response questions . . . . . . . . . . . . . . . . . . 683
Glossary
685
Answers
698
Included in the Interactive Textbook and PDF textbook only Appendix A: Guide to the TI-Nspire CAS Calculator (OS4) in VCE Mathematics Appendix B: Guide to the Casio ClassPad II CAS Calculator in VCE Mathematics
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Introduction SpecialistMathematicsAustralianCurriculum/VCEUnits1&2providesacompleteteaching andlearningresourcefortheVCEStudyDesigntobeimplementedin2016.Ithasbeen writtenwithunderstandingasitschiefaimandwithamplepracticeo↵eredthroughthe workedexamplesandexercises.Alltheworkhasbeentrialledintheclassroom,andthe approacheso↵eredarebasedonclassroomexperienceandtheresponsesofteacherstoearlier versionsofthisbook. SpecialistMathematicsUnits1&2o↵ersthematerialontopicsfromtheSpecialist MathematicsStudyDesign.Thetopicscoveredprovideexcellentbackgroundforastudent proceedingtoSpecialistMathematicsUnits3&4.Italsowouldbeveryusefulforastudent proceedingtoMathematicalMethodsUnits3&4. Thebookhasbeencarefullypreparedtoreflecttheprescribedcourse.Newmaterialhas beenincludedformanyofthetopicsincludinggeometry,proof,statistics,transformations, countingprinciplesandalgebra. Thebookcontainsfiverevisionchapters.Theseprovidetechnology-free,multiple-choiceand extended-responsequestions. TheTI-NspirecalculatorexamplesandinstructionshavebeencompletedbyRussellBrown andthosefortheCasioClassPadhavebeencompletedbyMariaScha↵ner.
AreasofStudy ThechaptersinthisbookcoverthediversityoftopicsthatfeatureintheSpecialist MathematicsStudyDesign.TheyarecollectedintoAreasofStudy.Topicsfrom(FOFSBM .BUIFNBUJDT6OJUT4UVEZ%FTJHODBOalsoCFincorporatedintoaSpecialist Mathematicscourse. ThetableshowshowcoursescanbeconstructedfromSpecialistMathematicstopics (indicatedbySM,withprescribedtopicsmarkedassuch)andGeneralMathematics topics(indicatedbyGM).‘ITBextra’referstoachapterthatisaccessedonlyinthe InteractiveTextbook.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Acknowledgements
The author and publisher wish to thank the following sources for permission to reproduce material: Cover: Used under license 2015 from Shutterstock.com / Tiago Ladeira. Images: Shutterstock.com / korinoxe, p.1 / AlexVector, p.39 / ILeysen, pp.82, 232 / Sianapotam, p.110 / pzAxe, p.146 / tashechka, pp.177, 316, 427, 453, 498, 629, 666, 679 / Apostrophe, p.190 / Dinga, p.265 / I_Mak, pp.334, 524, 640 / Attitude, pp.347, 387, 560, 598 / Melpomene, p.535 / Every e↵ort has been made to trace and acknowledge copyright. The publisher apologises for any accidental infringement and welcomes information that would redress this situation.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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An overview of the Cambridge complete teacher and learning resource
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Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Chapter 1
1 Algebra I
Objectives I I I I I I
To solve linear equations. To solve problems with linear equations and simultaneous linear equations. To use substitution and transposition with formulas. To add and multiply algebraic fractions. To solve literal equations. To solve simultaneous literal equations.
Algebra is the language of mathematics. Algebra helps us to state ideas more simply. It also enables us to make general statements about mathematics, and to solve problems that would be difficult to solve otherwise. We know by basic arithmetic that 9 ⇥ 7 + 2 ⇥ 7 = 11 ⇥ 7. We could replace the number 7 in this statement by any other number we like, and so we could write down infinitely many such statements. These can all be captured by the algebraic statement 9x + 2x = 11x, for any number x. Thus algebra enables us to write down general statements. Formulas enable mathematical ideas to be stated clearly and concisely. An example is the well-known formula for compound interest. Suppose that an initial amount P is invested at an interest rate R, with interest compounded annually. Then the amount, An , that the investment is worth after n years is given by An = P(1 + R)n . In this chapter we review some of the techniques which you have met in previous years. Algebra plays a central role in Specialist Mathematics at Years 11 and 12. It is important that you become fluent with the techniques introduced in this chapter and in Chapter 5.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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2
Chapter 1: Algebra I
1A Indices This section revises algebra involving indices.
Review of index laws For all non-zero real numbers a and b and all integers m and n: ⌅ am ⇥ an = am+n
⌅ am ÷ an = am
⌅
⌅ a
✓ a ◆n b
=
an bn
n
=
1 an
n
⌅ (am )n = amn ⌅
⌅ (ab)n = an bn
1 = an a n
Rational indices
⌅ a0 = 1
1
If a is a positive real number and n is a natural number, then a n is defined to be the nth root 1
1
of a. That is, a n is the positive number whose nth power is a. For example: 9 2 = 3. 1
1
If n is odd, then we can define a n when a is negative. If a is negative and n is odd, define a n 1
to be the number whose nth power is a. For example: ( 8) 3 = 2. In both cases we can write: ✓ 1 ◆n 1 p a n = n a with a n = a
m In general, the expression a x can be defined for rational indices, i.e. when x = , where m n and n are integers, by defining ✓ 1 ◆m m a n = an
To employ this definition, we will always first write the fractional power in simplest form. Note: The index laws hold for rational indices m and n whenever both sides of the equation
are defined (for example, if a and b are positive real numbers).
Example 1 Simplify each of the following: x4 a x2 ⇥ x3 b 2 x
1
4
1
d (x3 ) 2
c x2 ÷ x5
Solution
Explanation
a x2 ⇥ x3 = x2+3 = x5
am ⇥ an = am+n
b
x4 = x4 x2
2
4
1
1 4 5
c x2 ÷ x5 = x2 1
3
d (x3 ) 2 = x 2 Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
am = am an
= x2 =x
3 10
n
am = am n an (am )n = amn
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1A
1A Indices
3
Example 2 Evaluate: 2
a 125 3
b
Solution 1 ⌘2
⇣
2
a 125 3 = 125 3 b
✓ 1000 ◆ 2 3
27
=
✓ 1000 ◆ 2 3
27
Explanation 1 p3 125 3 = 125 = 5 ✓ 1000 ◆ 1 r 1000 10 3 3 = = 27 27 3
= 52 = 25
✓ 1000 ◆ 1 !2 3
27
=
✓ 10 ◆2 3
=
100 9
Example 3 Simplify
p4
x 2 y3
1 2 x2 y3
. Explanation
Solution p4 1 2 3 x2 y3 (x2 y3 ) 4 x4 y4 = 1 2 = 1 2 1 2 x2 y3 x2 y3 x2 y3
(ab)n = an bn am = am an
2 1 3 2 2 y4 3
= x4
1
n
= x0 y 12 1
a0 = 1
= y 12
Section summary ⌅ Index laws • am ⇥ an = am+n
• am ÷ an = am
•
• a
✓ a ◆n b
=
an bn
⌅ Rational indices 1
p
• an = n a
n
=
m
1 an
✓
n
• (am )n = amn
• (ab)n = an bn
•
• a0 = 1
1 = an a n
1 ◆m
• a n = an
Exercise 1A Example 1
1
Simplify each of the following using the appropriate index laws: a x3 ⇥ x4 e
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x8 x 4
b a5 ⇥ a f
p 5 p2
3
c x2 ⇥ x
1
1
2
g a2 ÷ a3
⇥ x2
d
y3 y7
h (a 2 )4
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4
1A
Chapter 1: Algebra I
i (y 2 )
7
j (x5 )3
1
1
m (n10 ) 5 ⇣ q 2n
2 ⌘5 5
÷ (43 n4 )
2
⇥
o (a2 ) 2 ⇥ a
4
t 22 p
3
1⌘ 4 2
3 2
r x3 ⇥ 2x 2 ⇥ 4x 3
x
1 x 4
p
1
1 a2 b
⇣
l
⇥ 43 p5 ÷ (6p 3 )
0
Evaluate each of the following: a
1 25 2
e
✓ 49 ◆
i
1 2
36
3 92
✓ 16 ◆ 1
b
1 64 3
c
f
1 27 3
g 144 2
j
✓ 81 ◆ 1
2
9
2
1
4
k
16
1 2
d 16 h 64 3
✓ 23 ◆0
3
l 128 7
5
3
Use your calculator to evaluate each of the following, correct to two decimal places: p p3 a 4.352 b 2.45 c 34.6921 d (0.02) 3 e 0.729 1 2 p4 1 f 2.3045 g (345.64) 3 h (4.568) 5 i 1 (0.064) 3
4
Simplify each of the following, giving your answer with positive index: a
a2 b3 a 2b 4
b
2a2 (2b)3 (2a) 2 b 4
c
a 2b a 2b
d
a2 b3 ab ⇥ 1 2 4 a b a b
e
(2a)2 ⇥ 8b3 16a 2 b 4
f
2a2 b3 16ab ÷ 2 4 8a b (2a) 1 b
1
Write
6
Write 2
7
Simplify each of the following:
8
x
⇥3 1
x
4
1
⇥ 62x ⇥ 32x ⇥ 22x as a power of 6. 2
a 23 ⇥ 26 ⇥ 2 3 ⇣ 1 ⌘2 ⇣ 1 ⌘5 d 23 ⇥ 22
1
2
1
b a 4 ⇥ a 5 ⇥ a 10 ⇣ 1 ⌘2 1 e 23 ⇥ 23 ⇥ 2
2
5
c 23 ⇥ 26 ⇥ 2
2 5
Simplify each of the following: p3 p3 p p a a3 b2 ÷ a2 b 1 b a3 b2 ⇥ a2 b 1 p p p p d a 4 b2 ⇥ a3 b 1 e a3 b2 c 3 ⇥ a2 b 1 c p p a3 b2 a 4 b2 p g 2 1 5 ⇥ 3 1 ⇥ a3 b 1 ab ab c
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
3
2n ⇥ 8n in the form 2an+b . 22n ⇥ 16
5
1
Example 3
4
3 20 5 ) 5
n 2x 2 ⇥ 4x3
s (ab3 )2 ⇥ a 2 b
Example 2
k (a
p5 a3 b2 ⇥ a2 b p5 p5 f a3 b2 ÷ a2 b
c 5
p5
2 3
1 1
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1B Standard form
5
1B Standard form Often when dealing with real-world problems, the numbers involved may be very small or very large. For example: ⌅ The distance from Earth to the Sun is approximately 150 000 000 kilometres. ⌅ The mass of an oxygen atom is approximately 0.000 000 000 000 000 000 000 026 grams.
To help deal with such numbers, we can use a more convenient way to express them. This involves expressing the number as a product of a number between 1 and 10 and a power of 10 and is called standard form or scientific notation. These examples written in standard form are: ⌅ 1.5 ⇥ 108 kilometres ⌅ 2.6 ⇥ 10
23
grams
Multiplication and division with very small or very large numbers can often be simplified by first converting the numbers into standard form. When simplifying algebraic expressions or manipulating numbers in standard form, a sound knowledge of the index laws is essential.
Example 4 Write each of the following in standard form: a 3 453 000
b 0.00675
Solution a 3 453 000 = 3.453 ⇥ 106
b 0.00675 = 6.75 ⇥ 10
3
Example 5 Find the value of
32 000 000 ⇥ 0.000 004 . 16 000
Solution 32 000 000 ⇥ 0.000 004 3.2 ⇥ 107 ⇥ 4 ⇥ 10 = 16 000 1.6 ⇥ 104 =
6
12.8 ⇥ 101 1.6 ⇥ 104
= 8 ⇥ 10
3
= 0.008
I Significant figures When measurements are made, the result is recorded to a certain number of significant figures. For example, if we say that the length of a piece of ribbon is 156 cm to the nearest centimetre, this means that the length is between 155.5 cm and 156.5 cm. The number 156 is said to be correct to three significant figures. Similarly, we may record ⇡ as being 3.1416, correct to five significant figures. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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6
Chapter 1: Algebra I
When rounding o↵ to a given number of significant figures, first identify the last significant digit and then: ⌅ if the next digit is 0, 1, 2, 3 or 4, round down ⌅ if the next digit is 5, 6, 7, 8 or 9, round up.
It can help with rounding o↵ if the original number is first written in scientific notation. So ⇡ = 3.141 592 653 . . . is rounded o↵ to 3, 3.1, 3.14, 3.142, 3.1416, 3.14159, etc. depending on the number of significant figures required. Writing a number in scientific notation makes it clear how many significant figures have been recorded. For example, it is unclear whether 600 is recorded to one, two or three significant figures. However, when written in scientific notation as 6.00 ⇥ 102 , 6.0 ⇥ 102 or 6 ⇥ 102 , it is clear how many significant figures are recorded.
Example 6 Evaluate
p5
a
b2
if a = 1.34 ⇥ 10
Solution p5 p5 a 1.34 ⇥ 10 10 = b2 (2.7 ⇥ 10 8 )2
10
and b = 2.7 ⇥ 10 8 .
1
(1.34 ⇥ 10 10 ) 5 = 2.72 ⇥ (10 8 )2
= 1.45443 . . . ⇥ 1013 = 1.45 ⇥ 1013
to three significant figures
Many calculators can display numbers in scientific notation. The format will vary from calculator to calculator. For example, the number 3 245 000 = 3.245 ⇥ 106 may appear as 3.245e6 or 3.24506 .
Using the TI-Nspire Insert a Calculator page, then use c on > Settings > Document Settings and change the Exponential Format field to Scientific. If you want this change to apply only to the current page, select OK to accept the change. Select Current to return to the current page.
Using the Casio ClassPad The ClassPad calculator can be set to express decimal answers in various forms. To select a fixed number of decimal places, including specifying scientific notation with a fixed decimal accuracy, go to Settings O and in Basic format tap the arrow to select from the various Number formats available.
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1B
1B Standard form
7
Section summary ⌅ A number is said to be in scientific notation (or standard form) when it is written as a
product of a number between 1 and 10 and an integer power of 10. For example: 6547 = 6.457 ⇥ 103 and 0.789 = 7.89 ⇥ 10 1 ⌅ Writing a number in scientific notation makes it clear how many significant figures have been recorded. ⌅ When rounding o↵ to a given number of significant figures, first identify the last significant digit and then: • if the next digit is 0, 1, 2, 3 or 4, round down • if the next digit is 5, 6, 7, 8 or 9, round up.
Exercise 1B Example 4
1
Express each of the following numbers in standard form: a 47.8 e 0.0023 i 23 000 000 000
2
c 79.23 g 12.000 34 k 165 thousand
d 43 580 h 50 million l 0.000 014 567
Express each of the following in scientific notation: a b c d e f
3
b 6728 f 0.000 000 56 j 0.000 000 0013
X-rays have a wavelength of 0.000 000 01 cm. The mass of a hydrogen atom is 0.000 000 000 000 000 000 000 001 67 g. Visible light has wavelength 0.000 05 cm. One nautical mile is 1853.18 m. A light year is 9 461 000 000 000 km. The speed of light is 29 980 000 000 cm/s.
Express each of the following as an ordinary number: a The star Sirius is approximately 8.128 ⇥ 1013 km from Earth. b A single red blood cell contains 2.7 ⇥ 108 molecules of haemoglobin. c The radius of an electron is 2.8 ⇥ 10 13 cm.
4
Write each of the following in scientific notation, correct to the number of significant figures indicated in the brackets: a 456.89 d 0.04536
Example 5
Example 6
5
6
(4) (2)
Find the value of: 324 000 ⇥ 0.000 0007 a 4000
b 34567.23 e 0.09045
b
(2) (2)
c 5679.087 f 4568.234
(5) (5)
5 240 000 ⇥ 0.8 42 000 000
Evaluate the following correct to three significant figures: p3 p4 a a 9 a 4 if a = 2 ⇥ 10 and b = 3.215 b if a = 2 ⇥ 1012 and b = 0.05 b 4b4
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8
Chapter 1: Algebra I
1C Solving linear equations and simultaneous linear equations Many problems may be solved by first translating them into mathematical equations and then solving the equations using algebraic techniques. An equation is solved by finding the value or values of the variables that would make the statement true. Linear equations are simple equations that can be written in the form ax + b = 0. There are a number of standard techniques that can be used for solving linear equations.
Example 7 a Solve
x x −2= . 5 3
b Solve
x − 3 2x − 4 − = 5. 2 3
Solution
3x − 5x = 30 −2x = 30 x= ∴
30 −2
x = −15
3(x − 3) − 2(2x − 4) = 30 3x − 9 − 4x + 8 = 30
3x − 4x = 30 + 9 − 8 −x = 31 x=
The intersection point of two straight lines can be found graphically; however, the accuracy of the solution will depend on the accuracy of the graphs. Alternatively, the intersection point may be found algebraically by solving the pair of simultaneous equations. We shall consider two techniques for solving simultaneous equations.
y 4 3 2 1 –3 –2 –1 O –1 –2 –3 –4
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x = −31
∴
" Simultaneous linear equations
31 −1
=4
3x − 30 = 5x
2x − 4 x−3 ×6− ×6=5×6 2 3
–y
x x × 15 − 2 × 15 = × 15 5 3
b Multiply both sides of the equation by the lowest common multiple of 2 and 3: x − 3 2x − 4 − =5 2 3
2x
a Multiply both sides of the equation by the lowest common multiple of 3 and 5: x x −2= 5 3
1
2
x
3 x+
(1, –2)
2y =
–3
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1C Solving linear equations and simultaneous linear equations
9
Example 8 Solve the equations 2x
y = 4 and x + 2y = 3. Explanation
Solution Method 1: Substitution
2x
y=4
(1)
x + 2y = 3
Using one of the two equations, express one variable in terms of the other variable.
(2)
From equation (2), we get x = 3
2y.
Substitute in equation (1): 2( 3 6
2y)
y=4
4y
y=4
Then substitute this expression into the other equation (reducing it to an equation in one variable, y). Solve the equation for y.
5y = 10 y= 2 Substitute the value of y into (2): x + 2( 2) = 3
Substitute this value for y in one of the equations to find the other variable, x.
x=1 Check in (1): LHS = 2(1)
( 2) = 4
RHS = 4
A check can be carried out with the other equation.
Method 2: Elimination
2x
y=4
x + 2y = 3
(1) (2)
To eliminate x, multiply equation (2) by 2 and subtract the result from equation (1). When we multiply equation (2) by 2, the pair of equations becomes: 2x
y=4
(1)
If one of the variables has the same coefficient in the two equations, we can eliminate that variable by subtracting one equation from the other. It may be necessary to multiply one of the equations by a constant to make the coefficients of x or y the same in the two equations.
(20 )
2x + 4y = 6 Subtract (20 ) from (1): 5y = 10 y= 2
Now substitute for y in equation (2) to find x, and check as in the substitution method. Note: This example shows that the point (1, 2) is the point of intersection of the graphs of
the two linear relations. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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10
Chapter 1: Algebra I
Using the TI-Nspire Calculator application
Simultaneous equations can be solved in a Calculator application. ⌅ Use
menu
> Algebra > Solve System of Equations > Solve System of Equations.
⌅ Complete the pop-up screen. ⌅ Enter the equations as shown to give the
solution to the simultaneous equations 2x y = 4 and x + 2y = 3. Graphs application
Simultaneous equations can also be solved graphically in a Graphs application. ⌅ Equations of the form ax + by = c can be entered directly using Entry/Edit > Equation > Line > Line Standard.
menu
> Graph
⌅ Alternatively, rearrange each equation to make y the subject, and enter as a standard
function (e.g. f 1(x) = 2x
4).
Note: If the Entry Line is not visible, press
tab . Pressing enter will hide the Entry Line. If you want to add more equations, use H to add the next equation.
⌅ The intersection point is found using
> Analyze Graph > Intersection. ⌅ Move the cursor to the left of the intersection point (lower bound), click, and move to the right of the intersection point (upper bound). ⌅ Click to paste the coordinates to the screen.
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menu
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1C Solving linear equations and simultaneous linear equations
11
Using the Casio ClassPad To solve the simultaneous equations algebraically: # Open the M application and turn on the keyboard. # In
Math1
, tap the simultaneous equations icon ~.
# Enter the two equations as shown. # Type x, y in the bottom-right square to indicate the
variables. # Tap EXE . There are two methods for solving simultaneous equations graphically. Method 1
In the M application: # Enter the equation 2x − y = 4 and tap
EXE .
# Enter the equation x + 2y = −3 and tap
EXE .
# Select $ from the toolbar to insert a graph
window. An appropriate window can be set by selecting Zoom > Quick > Quick Standard. # Highlight each equation and drag it into the graph window. # To find the point of intersection, go to Analysis > G-Solve > Intersection.
Method 2
For this method, the equations need to be rearranged to make y the subject. In this form, the equations are y = 2x − 4 and y = − 12 x − 32 . # Open the menu # # # # # #
; select Graph & Table . Tap in the working line of y1 and enter 2x − 4. Tap in the working line of y2 and enter − 12 x − 32 . Tick the boxes for y1 and y2. Select $ from the toolbar. Go to Analysis > G-Solve > Intersection. If necessary, the view window settings can be or by selecting Zoom > adjusted by tapping Quick > Quick Standard.
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12
1C
Chapter 1: Algebra I
Section summary ⌅ An equation is solved by finding the value or values of the variables that would make
the statement true. ⌅ A linear equation is one in which the ‘unknown’ is to the first power. ⌅ There are often several di↵erent ways to solve a linear equation. The following steps provide some suggestions: 1 Expand brackets and, if the equation involves fractions, multiply through by the lowest common denominator of the terms. 2 Group all of the terms containing a variable on one side of the equation and the terms without the variable on the other side. ⌅ Methods for solving simultaneous linear equations in two variables by hand: Substitution • Make one of the variables the subject in one of the equations. • Substitute for that variable in the other equation. Elimination • Choose one of the two variables to eliminate.
• Obtain the same or opposite coefficients for this variable in the two equations.
To do this, multiply both sides of one or both equations by a number. • Add or subtract the two equations to eliminate the chosen variable.
Exercise 1C Example 7a
1
Solve the following linear equations: a 3x + 7 = 15 d
2x 3
15 = 27
g 3x + 5 = 8 7x x j 6x + 4 = 3 3 Example 7b
2
b 8
x = 16 2
e 5(2x + 4) = 13
f
h 2 + 3(x
i
Solve the following linear equations: x 2x a + = 16 2 5 3x 2 x c + = 8 2 4 x 4 2x + 5 e + =6 2 4 3 x 2(x + 1) g = 24 4 5
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
c 42 + 3x = 22
4) = 4(2x + 5)
3(4 2x 5
5x) = 24 3 = 5x 4
3x x =8 4 3 5x 4 2x d = 4 3 5 3 3x 2(x + 5) 1 f = 10 6 20 2(5 x) 6 4(x 2) h + = 8 7 3 b
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1C Example 8
1D Solving problems with linear equations
3
13
Solve each of the following pairs of simultaneous equations: a 3x + 2y = 2 2x
3y = 6
d x + 2y = 12 x
3y = 2
b 5x + 2y = 4 3x e 7x
y=6
c
2x 3x
y=7 2y = 2
3y = 6
f 15x + 2y = 27
x + 5y = 10
3x + 7y = 45
1D Solving problems with linear equations Many problems can be solved by translating them into mathematical language and using an appropriate mathematical technique to find the solution. By representing the unknown quantity in a problem with a symbol (called a pronumeral or a variable) and constructing an equation from the information, the value of the unknown can be found by solving the equation. Before constructing the equation, each variable and what it stands for (including the units) should be stated. All the elements of the equation must be in units of the same system.
Example 9 For each of the following, form the relevant linear equation and solve it for x: a The length of the side of a square is (x 6) cm. Its perimeter is 52 cm. b The perimeter of a square is (2x + 8) cm. Its area is 100 cm2 . Solution a Perimeter = 4 ⇥ side length Therefore 4(x x and so
6) = 52 6 = 13 x = 19
b The perimeter of the square is 2x + 8. 2x + 8 x + 4 The length of one side is = . 4 2 Thus the area is ✓ x + 4 ◆2 = 100 2
As the side length must be positive, this gives the linear equation x+4 = 10 2 Therefore x = 16.
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14
Chapter 1: Algebra I
Example 10 An athlete trains for an event by gradually increasing the distance she runs each week over a five-week period. If she runs an extra 5 km each successive week and over the five weeks runs a total of 175 km, how far did she run in the first week? Solution Let the distance run in the first week be x km. Then the distance run in the second week is x + 5 km, and the distance run in the third week is x + 10 km, and so on. The total distance run is x + (x + 5) + (x + 10) + (x + 15) + (x + 20) km. )
5x + 50 = 175 5x = 125 x = 25
The distance she ran in the first week was 25 km.
Example 11 A man bought 14 CDs at a sale. Some cost $15 each and the remainder cost $12.50 each. In total he spent $190. How many $15 CDs and how many $12.50 CDs did he buy? Solution Let n be the number of CDs costing $15. Then 14 n is the number of CDs costing $12.50. )
15n + 12.5(14 15n + 175
n) = 190
12.5n = 190
2.5n + 175 = 190 2.5n = 15 n=6 He bought 6 CDs costing $15 and 8 CDs costing $12.50.
Section summary Steps for solving a word problem with a linear equation ⌅ Read the question carefully and write down the known information clearly. ⌅ Identify the unknown quantity that is to be found. ⌅ Assign a variable to this quantity. ⌅ Form an expression in terms of x (or the variable being used) and use the other relevant
information to form the equation. ⌅ Solve the equation. ⌅ Write a sentence answering the initial question.
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1D
1D Solving problems with linear equations
15
Exercise 1D Skillsheet
1
For each of the cases below, write down a relevant equation involving the variables defined, and solve the equation for parts a, b and c. a The length of the side of a square is (x 2) cm. Its perimeter is 60 cm. b The perimeter of a square is (2x + 7) cm. Its area is 49 cm2 . c The length of a rectangle is (x 5) cm. Its width is (12 x) cm. The rectangle is twice as long as it is wide. d The length of a rectangle is (2x + 1) cm. Its width is (x 3) cm. The perimeter of the rectangle is y cm. e n people each have a meal costing $p. The total cost of the meal is $Q. f S people each have a meal costing $p. A 10% service charge is added to the cost. The total cost of the meal is $R. g A machine working at a constant rate produces n bolts in 5 minutes. It produces 2400 bolts in 1 hour. h The radius of a circle is (x + 3) cm. A sector subtending an angle of 60 at the centre is cut o↵. The arc length of the minor sector is a cm.
Example 9
Example 10
2
Bronwyn and Noel have a women’s clothing shop in Summerland. Bronwyn manages the shop and her sales are going up steadily over a particular period of time. They are going up by $500 per week. If over a five-week period her sales total $17 500, how much did she earn in the first week?
Example 11
3
Bronwyn and Noel have a women’s clothing shop in Summerland. Sally, Adam and baby Lana came into the shop and Sally bought dresses and handbags. The dresses cost $65 each and the handbags cost $26 each. Sally bought 11 items and in total she spent $598. How many dresses and how many handbags did she buy?
4
A rectangular courtyard is three times as long as it is wide. If the perimeter of the courtyard is 67 m, find the dimensions of the courtyard.
5
A wine merchant buys 50 cases of wine. He pays full price for half of them, but gets a 40% discount on the remainder. If he paid a total of $2260, how much was the full price of a single case?
6
A real-estate agent sells 22 houses in six months. He makes a commission of $11 500 per house on some and $13 000 per house on the remainder. If his total commission over the six months was $272 500, on how many houses did he make a commission of $11 500?
7
Three boys compare their marble collections. The first boy has 14 fewer than the second boy, who has twice as many as the third. If between them they have 71 marbles, how many does each boy have?
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16
Chapter 1: Algebra I
1D
8
Three girls are playing Scrabble. At the end of the game, their three scores add up to 504. Annie scored 10% more than Belinda, while Cassie scored 60% of the combined scores of the other two. What did each player score?
9
A biathlon event involves running and cycling. Kim can cycle 30 km/h faster than she can run. If Kim spends 48 minutes running and a third as much time again cycling in an event that covers a total distance of 60 km, how fast can she run?
10
The mass of a molecule of a certain chemical compound is 2.45 ⇥ 10 22 g. If each molecule is made up of two carbon atoms and six oxygen atoms and the mass of an oxygen atom is one-third that of a carbon atom, find the mass of an oxygen atom.
11
Mother’s pearl necklace fell to the floor. One-sixth of the pearls rolled under the fridge, one-third rolled under the couch, one-fifth of them behind the book shelf, and nine were found at her feet. How many pearls are there?
12
Parents say they don’t have favourites, but everyone knows that’s a lie. A father distributes $96 to his three children according to the following instructions: The middle child receives $12 less than the oldest, and the youngest receives one-third as much as the middle child. How much does each receive?
13
Kavindi has achieved an average mark of 88% on her first four maths tests. What mark would she need on her fifth test to increase her average to 90%?
14
In a particular class, 72% of the students have black hair. Five black-haired students leave the class, so that now 65% of the students have black hair. How many students were originally in the class?
15
Two tanks are being emptied. Tank A contains 100 litres of water and tank B contains 120 litres of water. Water runs from Tank A at 2 litres per minute, and water runs from tank B at 3 litres per minute. After how many minutes will the amount of water in the two tanks be the same?
16
Suppose that candle A is initially 10 cm tall and burns out after 2 hours. Candle B is initially 8 cm tall and burns out after 4 hours. Both candles are lit at the same time. Assuming ‘constant burning rates’: a When is the height of candle A the same as the height of candle B? b When is the height of candle A half the height of candle B? c When is candle A 1 cm taller than candle B?
17
10 A motorist drove 320 km in hours. He drove part of the way at an average speed 3 of 100 km/h and the rest of the way at an average speed of 90 km/h. What is the distance he travelled at 100 km/h?
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1D
1E Solving problems with simultaneous linear equations
18
17
14 hours if she travels at her Jarmila travels regularly between two cities. She takes 3 usual speed. If she increase her speed by 3 km/h, she can reduce her time taken by 20 minutes. What is her usual speed?
1E Solving problems with simultaneous linear equations When the relationship between two quantities is linear, we can find the constants which determine this linear relationship if we are given two sets of information satisfying the relationship. Simultaneous linear equations enable this to be done. Another situation in which simultaneous linear equations may be used is where it is required to find the point of the Cartesian plane which satisfies two linear relations.
Example 12 There are two possible methods for paying gas bills: A fixed charge of $25 per quarter + 50c per unit of gas used Method B A fixed charge of $50 per quarter + 25c per unit of gas used Method A
Determine the number of units which must be used before method B becomes cheaper than method A. Solution C1 = charge ($) using method A
Let
C2 = charge ($) using method B
C 100
C1 = 0.5x + 25
Then
C1 = 25 + 0.5x C2 = 50 + 0.25x
Dollars
x = number of units of gas used
C2 = 0.25x + 50 50 25 O
25 50 75 100 125 150 Units
x
From the graph we see that method B is cheaper if the number of units exceeds 100. The solution can be obtained by solving simultaneous linear equations: C1 = C2 25 + 0.5x = 50 + 0.25x 0.25x = 25 x = 100
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18
1E
Chapter 1: Algebra I
Example 13 If 3 kg of jam and 2 kg of butter cost $29, and 6 kg of jam and 3 kg of butter cost $54, find the cost per kilogram of jam and butter. Solution Let the cost of 1 kg of jam be x dollars and the cost of 1 kg of butter be y dollars. Then
3x + 2y = 29
(1)
and
6x + 3y = 54
(2)
Multiply (1) by 2:
6x + 4y = 58
(10 )
Subtract (10 ) from (2):
y= 4 y=4
Substitute in (2):
6x + 3(4) = 54 6x = 42 x=7
Jam costs $7 per kilogram and butter costs $4 per kilogram.
Section summary Steps for solving a word problem with simultaneous linear equations ⌅ Read the question carefully and write down the known information clearly. ⌅ Identify the two unknown quantities that are to be found. ⌅ Assign variables to these two quantities. ⌅ Form expressions in terms of x and y (or other suitable variables) and use the other
relevant information to form the two equations. ⌅ Solve the system of equations. ⌅ Write a sentence answering the initial question.
Exercise 1E Example 12
Example 13
1
A car hire firm o↵ers the option of paying $108 per day with unlimited kilometres, or $63 per day plus 32 cents per kilometre travelled. How many kilometres would you have to travel in a given day to make the unlimited-kilometres option more attractive?
2
Company A will cater for your party at a cost of $450 plus $40 per guest. Company B o↵ers the same service for $300 plus $43 per guest. How many guests are needed before Company A’s charge is less than Company B’s?
3
A basketball final is held in a stadium which can seat 15 000 people. All the tickets have been sold, some to adults at $45 and the rest for children at $15. If the revenue from the tickets was $525 000, find the number of adults who bought tickets.
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1E
1F Substitution and transposition of formulas
19
4
A contractor employed eight men and three boys for one day and paid them a total of $2240. Another day he employed six men and eighteen boys for $4200. What was the daily rate he paid each man and each boy?
5
The sum of two numbers is 212 and their di↵erence is 42. Find the two numbers.
6
A chemical manufacturer wishes to obtain 700 litres of a 24% acid solution by mixing a 40% solution with a 15% solution. How many litres of each solution should be used?
7
Two children had 220 marbles between them. After one child had lost half her marbles and the other had lost 40 marbles, they had an equal number of marbles. How many did each child start with and how many did each child finish with?
8
An investor received $31 000 interest per annum from a sum of money, with part of it invested at 10% and the remainder at 7% simple interest. She found that if she interchanged the amounts she had invested she could increase her return by $1000 per annum. Calculate the total amount she had invested.
9
Each adult paid $30 to attend a concert and each student paid $20. A total of 1600 people attended. The total paid was $37 000. How many adults and how many students attended the concert?
1F Substitution and transposition of formulas An equation that states a relationship between two or more quantities is called a formula; e.g. the area of a circle is given by A = ⇡r2 . The value of A, the subject of the formula, may be found by substituting a given value of r and the value of ⇡.
Example 14 Using the formula A = ⇡r2 , find the value of A correct to two decimal places if r = 2.3 and ⇡ = 3.142 (correct to three decimal places). Solution A = ⇡r2 = 3.142(2.3)2 = 16.62118 )
A = 16.62
correct to two decimal places
The formula A = ⇡r2 can also be transposed to make r the subject. When transposing a formula, follow a similar procedure to solving a linear equation. Whatever has been done to the variable required is ‘undone’.
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20
1F
Chapter 1: Algebra I
Example 15 a Transpose the formula A = ⇡r2 to make r the subject. b Hence find the value of r correct to three decimal places if A = 24.58 and ⇡ = 3.142 (correct to three decimal places). Solution a
A = ⇡r A = r2 ⇡ r r=
2
b r=
r
A = ⇡
r
24.58 3.142
= 2.79697 . . . A ⇡
r = 2.797 correct to three decimal places
Section summary ⌅ A formula relates di↵erent quantities: for example, the formula A = ⇡r2 relates the
radius r with the area A of the circle. ⌅ The variable on the left is called the subject of the formula: for example, in the formula A = ⇡r2 , the subject is A. ⌅ To calculate the value of a variable which is not the subject of a formula: Method 1 Substitute the values for the known variables, then solve the resulting equation for the unknown variable. Method 2 Rearrange to make the required variable the subject, then substitute values.
Exercise 1F Example 14
1
Substitute the specified values to evaluate each of the following, giving the answers correct to two decimal places: a v if v = u + at PrT b I if I = 100 c V if V = ⇡r2 h
and u = 15, a = 2, t = 5
d S if S = 2⇡r(r + h) 4 e V if V = ⇡r2 h 3 1 f s if s = ut + at2 r2 ` g T if T = 2⇡ g 1 1 1 h f if = + f v u 2 i c if c = a2 + b2
and r = 10.2, h = 15.6
2
2
j v if v = u + 2as Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
and P = 600, r = 5.5, T = 10 and r = 4.25, h = 6 and r = 3.58, h = 11.4 and u = 25.6, t = 3.3, a = 1.2 and ` = 1.45, g = 9.8 and v = 3, u = 7 and a = 8.8, b = 3.4 and u = 4.8, a = 2.5, s = 13.6
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1F Example 15
1F Substitution and transposition of formulas
2
Transpose each of the following to make the symbol in brackets the subject: n a v = u + at (a) b S = (a + `) (`) 2 1 c A = bh (b) d P = I2R (I) 2 1 1 e s = ut + at2 (a) f E = mv2 (v) 2 2 p g Q = 2gh (h) h xy z = xy + z (x) i
3
21
ax + by =x c
b
(x)
j
mx + b =c x b
(x)
9C The formula F = + 32 is used to convert temperatures given in degrees Celsius (C) 5 to degrees Fahrenheit (F). a Convert 28 degrees Celsius to degrees Fahrenheit. b Transpose the formula to make C the subject and find C if F = 135 .
4
The sum, S , of the interior angles of a polygon with n sides is given by the formula S = 180(n 2). a Find the sum of the interior angles of an octagon. b Transpose the formula to make n the subject and hence determine the number of sides of a polygon whose interior angles add up to 1260 .
5
1 The volume, V, of a right cone is given by the formula V = ⇡r2 h, where r is the radius 3 of the base and h is the height of the cone. a Find the volume of a cone with radius 3.5 cm and height 9 cm. b Transpose the formula to make h the subject and hence find the height of a cone with base radius 4 cm and volume 210 cm3 . c Transpose the formula to make r the subject and hence find the radius of a cone with height 10 cm and volume 262 cm3 .
6
For a particular type of sequence of numbers, the sum (S ) of the terms in the sequence is given by the formula n S = (a + `) 2 where n is the number of terms in the sequence, a is the first term and ` is the last term. a Find the sum of such a sequence of seven numbers whose first term is 3 and whose last term is 22. b What is the first term of such a sequence of 13 numbers whose last term is 156 and whose sum is 1040? c How many terms are there in the sequence 25 + 22 + 19 + · · · + ( 5) = 110?
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22
Chapter 1: Algebra I
1G Algebraic fractions The principles involved in addition, subtraction, multiplication and division of algebraic fractions are the same as for simple numerical fractions.
I Addition and subtraction To add or subtract, all fractions must be written with a common denominator.
Example 16 Simplify: x x a + 3 4 5 c x+2
2 3a + x 4 4 7 d x + 2 (x + 2)2 b
4 x
1
Solution x x 4x + 3x a + = 3 4 12 7x = 12 c
5 x+2
4 x
1
=
5(x 1) 4(x + 2) (x + 2)(x 1)
=
5x 5 4x 8 (x + 2)(x 1)
=
x 13 (x + 2)(x 1)
b
2 3a 8 + 3ax + = x 4 4x
d
4 x+2
7 4(x + 2) 7 = 2 (x + 2) (x + 2)2 =
4x + 1 (x + 2)2
I Multiplication and division Before multiplying and dividing algebraic fractions, it is best to factorise numerators and denominators where possible so that common factors can be readily identified.
Example 17 Simplify: 3x2 5y a ⇥ 2 12x 10y c
x2 2x
1 4x ⇥ 2 x2 + 4x + 3
b
2x 4 x2 1 ⇥ x 1 x 2
d
x2 + 3x x2 x
10 x2 + 6x + 5 ÷ 3x + 3 2
Solution a
3x2 5y x ⇥ = 2 12x 8y 10y
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1G Algebraic fractions
b
23
2x 4 x2 1 2(x 2) (x 1)(x + 1) ⇥ = ⇥ x 1 x 2 x 1 x 2 = 2(x + 1)
c
x2 2x
d
x2 + 3x x2 x
4x (x 1)(x + 1) 4x 1 ⇥ 2 = ⇥ 2 x + 4x + 3 2(x 1) (x + 1)(x + 3) 2x = x+3 10 x2 + 6x + 5 (x + 5)(x 2) 3(x + 1) ÷ = ⇥ 3x + 3 (x 2)(x + 1) (x + 1)(x + 5) 2 3 = x+1
I More examples The following two examples involve algebraic fractions and rational indices.
Example 18 p 3x3 Express p + 3x2 4 4 x Solution p 3x3 + 3x2 4 p 4 x
x as a single fraction. p p 3x3 + 3x2 4 x 4 x= p 4 x 3 2 3x + 3x (4 x) = p 4 x 12x2 = p 4 x
x
Example 19 Express (x Solution (x
1
4) 5 1
4) 5
(x (x
4) 4)
4 5
4 5
as a single fraction.
= (x
1
1
4) 5
4
(x = =
(x x (x
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1
4) 5 (x (x 5
4) 5 4
4) 5
1
4 4) 5
4
4) 5
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24
1G
Chapter 1: Algebra I
Section summary ⌅ Simplifying algebraic fractions • First factorise the numerator and denominator.
• Then cancel any factors common to the numerator and denominator.
⌅ Adding and subtracting algebraic fractions
• First obtain a common denominator and then add or subtract.
⌅ Multiplying and dividing algebraic fractions
• First factorise each numerator and denominator completely.
• Then complete the calculation by cancelling common factors.
Exercise 1G Skillsheet
1
Example 16
Simplify each of the following: 2x 3x a + b 3 2 3x y x d e 4 6 3 g j m o q
Example 17
2
3 x
2
a
2 a 3
x x
+
2 x+1
h
+
a 3a + 4 8
k 2x
1
+
(x
2
+
x2
5 3 x
3a 2 3 + x
a 4
3h 5h 3h + 4 8 2 5 2 f + x 1 x
c
2 y
2x x+3
4x x
6x2 4 5x
2 1)(x + 4)
n
3 2 + + 5x + 6 x + 3
4x 1
1
3 2
3
x
2
p x
y
r
x
3
3 x
2
Simplify each of the following: x2 4y3 3x2 y2 a ⇥ b ⇥ 2y x 4y 6x d
x2 3xy ÷ 2y 6
e
g
(x 1)2 x2 + 3x 4
h
j
5a2 10a ÷ 6b 12b2
k
m
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2x x
1
÷
4x2 x2
1
n
4
x 3a
x2
⇥
x x
x
4
x
6 3
2 x
a2
÷
x2 4 2x2
x2 9 3x + 6 9 ⇥ ÷ x+2 x 3 x
i
4 3 + x + 1 (x + 1)2
l
2 x+4
x2
3 + 8x + 16
2 4 + 2 x+2 x 4 1 x +
y 2x
2
x
c
4x3 12 ⇥ 4 3 8x
f
2x + 5 4x2 + 10x
i
x2 5x + 4 x2 4x
l
x+2 4x + 8 ÷ x(x 3) x2 4x + 3
o
3x 6x2 2 ÷ ⇥ 9x 6 x 2 x + 5
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1G 3
Express each of the following as a single fraction: 1 2 2 2 a + b + x 3 x 3 x 4 x 3 2x 2 1 2 d + e + 2 x 3 x+4 x 5 (x 5) 2 3 x 3 1 2 j 2 x 5 (x 5)
g
Example 18
4
1
5
3 2 + x+4 x 3 3x 2 f + 2 x 4 (x 4)
c
2
5 3 x+4 2x 2 k 3 (x 6) (x 6)2
h
x
2x 3x + x 3 x+3 2x + 3 2x 4 l x 4 x 3 i
x
Express each of the following as a single fraction: p 2 2 2 a 1 x+ p b p + 1 x x 4 3 d p
Example 19
25
1H Literal equations
3 x+4
+
p
p 3x2 x + 4
3x3 e p x+4
x+4
c p f
3
+p
x+4
2 x+4
p 3x3 + 3x2 x + 3 p 2 x+3
Simplify each of the following: a (6x
1
3) 3
(6x
3)
2 3
1
b (2x + 3) 3
2x(2x + 3)
2 3
c (3
1
x) 3
2x(3
x)
2 3
1H Literal equations A literal equation in x is an equation whose solution will be expressed in terms of pronumerals rather than numbers. For the equation 2x + 5 = 7, the solution is the number 1. c b For the literal equation ax + b = c, the solution is x = . a Literal equations are solved in the same way as numerical equations. Essentially, the literal equation is transposed to make x the subject.
Example 20 Solve the following for x: a px
q=r
a b = +c x 2x
b ax + b = cx + d
c
b
c Multiply both sides by 2x:
Solution a px
)
q=r
ax + b = cx + d
px = r + q
ax
cx = d
b
r+q p
x(a
c) = d
b
d a
b c
x=
)
x=
a b = +c x 2x 2a = b + 2xc 2a )
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b = 2xc x=
2a b 2c
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26
Chapter 1: Algebra I
I Simultaneous literal equations Simultaneous literal equations are solved by the same methods that are used for solving simultaneous equations, i.e. substitution and elimination.
Example 21 Solve each of the following pairs of simultaneous equations for x and y: a y = ax + c
b ax
y = bx + d
y=c
x + by = d
Solution a Equate the two expressions for y: ax + c = bx + d
Thus and
b We will use the method of elimination, and eliminate y. First number the two equations:
ax
bx = d
c
x(a
b) = d
c
ax
y=c
(1)
d a
c b
x + by = d
(2)
x=
y=a =
✓d
ad
ad = a
a
c◆ +c b
ac + ac a b bc b
Multiply (1) by b: abx bc
(10 )
by = bc
Add (10 ) and (2): abx + x = bc + d x(ab + 1) = bc + d )
x=
bc + d ab + 1
Substitute in (1): y = ax c ✓ bc + d ◆ =a ab + 1 =
c
ad c ab + 1
Section summary ⌅ An equation for the variable x in which all the coefficients of x, including the constants,
are pronumerals is known as a literal equation. ⌅ The methods for solving linear literal equations or simultaneous linear literal equations are exactly the same as when the coefficients are given numbers.
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1H
1H Literal equations
27
Exercise 1H Example 20
1
Solve each of the following for x: a ax + n = m
b ax + b = bx
ax +c=0 b
d px = qx + 5
c
e mx + n = nx g i k m
Example 21
b x
a
=
2b x+a
b(ax + b) = a(bx x a p
1= qx t
1 b = x+a x x x h +n= +m m n f
m
j p2 (1
a)
x +2 b
+p=
2pqx = q2 (1 + x)
2x 1 = a + b a2 b2 1 1 2 n + = x + a x + 2a x + 3a l
qx t p
x
x)
a
b
+
2
For the simultaneous equations ax + by = p and bx bp aq and y = 2 . a + b2
3
For the simultaneous equations
4
Solve each of the following pairs of simultaneous equations for x and y: a ax + y = c
b ax
by = a2
x + by = d
bx
ay = b2
ax
ap + bq a2 + b 2
x y x y ab + = 1 and + = 1, show that x = y = . a b b a a+b
d ax + by = a2 + 2ab
c ax + by = t
b2
bx + ay = a2 + b2
by = s
e (a + b)x + cy = bc
f 3(x
(b + c)y + ax = ab 5
ay = q, show that x =
a)
2(y + a) = 5
2(x + a) + 3(y
4a
a) = 4a
1
Write s in terms of a only in the following pairs of equations: a s = ah
b s = ah
c as = a + h
h = 2a + 1
h = a(2 + h)
d as = s + h
e s = h2 + ah
ah = a + h
h = 3a
g s = 2 + ah + h2 1 h=a a
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
h 3s
2
h + ah = 1 f as = a + 2h h=a
s
ah = a2
as + 2h = 3a
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28
Chapter 1: Algebra I
1I Using a CAS calculator for algebra Using the TI-Nspire This section demonstrates the basic algebra commands of the TI-Nspire. To access them, open a Calculator application ( c on > New Document > Add Calculator) and select menu > Algebra. The three main commands are solve, factor and expand. 1: Solve
This command is used to solve equations, simultaneous equations and some inequalities. An approximate (decimal) answer can be obtained by pressing a decimal number in the expression.
ctrl enter
or by including
The following screens illustrate its use.
2: Factor
This command is used for factorisation. Factorisation over the rational numbers is obtained by not specifying the variable, whereas factorisation over the real numbers is obtained by specifying the variable. The following screens illustrate its use.
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1I Using a CAS calculator for algebra
29
3: Expand
This command is used for expanding out expressions. By specifying the variable, the expanded expression will be ordered in decreasing powers of that variable. Symbolic expressions can only be expanded for an appropriate domain.
Using the Casio ClassPad This section explores the M application. The Interactive menu is easiest to use with the stylus and the soft keyboards Math1 , Math2 and Math3 . Solve
This is used to solve equations and inequalities. The variables x, y and z are found on the hard keyboard. Other variables may be entered using the Var keyboard. Variables are shown in bold italics. Note: The
keyboard allows you to type text; however, the letters are not always recognised as variables. If you use the abc keyboard for variables, then you must type a ⇥ x, for example, because ax will be treated as text. abc
Examples: ⌅ Enter ax + b = 0 and highlight it with the stylus. Go to Interactive > Equation/Inequality > solve
and ensure the variable selected is x. ⌅ Enter x2 + x 1 and follow the same instructions as above. Note that ‘= 0’ has been omitted in this example. It is not necessary to enter the right-hand side of an equation if it is zero. ⌅ To solve abt w + t = wt for w, select w as the variable. ⌅ Solve x3 x2 x + 1 = 0 for x.
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30
Chapter 1: Algebra I
More examples: p ⌅ Solve 2x + 2 < 3 for x. Note: For the square root, use 5 from
Math1
The inequality signs (, , ) are in
. Math3
.
⌅ If the answer is not in the form required, it is often
possible to cut and paste it into the next entry line and use Interactive > Transformation > simplify as shown on the right. ⌅ To solve a pair of simultaneous equations, tap ~
from the Math1 keyboard and enter the equations and variables as shown. ⌅ For more than two equations, tap ~ until the required number of equations is displayed. Factor
To factorise is to write an expression as a product of simpler expressions. This command is found in Interactive > Transformation > factor.
Examples: ⌅ To factorise x3 use factor.
2x over the rational numbers,
⌅ To factorise over the real numbers, use rFactor.
More examples: ⌅ Factorise a2 ⌅ Factorise a3 ⌅ Factorise
2
b2 . b3 .
1
+ 1. x 1 (x 1)2 ⌅ Factorise 2x4 x2 over the rationals. ⌅ Factorise 2x4 x2 over the reals. +
This command can also be used to give the prime decomposition (factors) of integers.
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1I Using a CAS calculator for algebra
31
Expand
An expression can be expanded out by using Interactive > Transformation > expand. Examples: ⌅ Expand (a + b)3 . ⌅ Expand (a + b)2 .
This command can also be used to form partial fractions. In this case, enter and highlight the expression, go to Interactive > Transformation > expand, select the Partial Fraction option as shown on the right, and set the variable as x.
Examples: ⌅ Expand ⌅ Expand
1 x2
1
.
x3 + 2x + 1 . x2 1
Zeroes
To find the zeroes of an expression in M, select Interactive > Equation/Inequality > solve and ensure that you set the variable. The calculator assumes that you are solving an equation for which one side is zero. Examples: ⌅ Zeroes of x2 ⌅ Zeroes of x
2
⌅ Zeroes of x2 ⌅ Zeroes of x2 ⌅ Zeroes of x2 ⌅ Zeroes of x2 ⌅ Zeroes of x2
1 for x. y2 for y. y2 for x. y for y. 4x + 8 for x. No solutions. 4x + 1 for x. Two solutions. 4x + 4 for x. One solution.
Approximate
Switch mode in the status bar to Decimal. If an answer is given in Standard (exact) mode, it can be converted by highlighting the answer and tapping u in the toolbar.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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32
1I
Chapter 1: Algebra I Combining fractions
This command returns the answer as a single fraction with the denominator in factored form. Examples: ⌅ Enter and highlight 1/(x 1) + 1/(x + 1). Then select Interactive > Transformation > combine. ⌅ Enter and highlight y/(x y) + y/(x + y). Then select Interactive > Transformation > combine.
Exercise 1I This exercise provides practice in some of the skills associated with a CAS calculator. Other exercises in this chapter can be attempted with CAS, but it is recommended that you also use this chapter to develop your ‘by hand’ skills. 1
2
Solve each of the following equations for x: a(a x) b(b + x) a =x b 2(x 3) + (x 2)(x b a x+a x x+a x+c c =1 d + =2 x+b x b x c x a
33
Factorise each of the following: a x 2 y2 x 2 y2 + 1 c a4 8a2 b 48b2
3
4) = x(x + 1)
b x3 2 x + 2x2 d a2 + 2bc (c2 + 2ab)
Solve each of the following pairs of simultaneous equations for x and y: a axy + b = (a + c)y
b x(b
bxy + a = (b + c)y
y(c
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
c) + by a)
c=0
ax + c = 0
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Chapter 1 review
33
⌅ Indices AS Nrich
• am ⇥ an = am+n
✓ a ◆n
• am ÷ an = am
n
• (am )n = amn
• (ab)n = an bn
1 p an 1 • a n= n • a0 = 1 • an = n a n b b a ⌅ A number is expressed in standard form or scientific notation when written as a product of a number between 1 and 10 and an integer power of 10; e.g. 1.5 ⇥ 108
•
Review
Chapter summary
=
⌅ Linear equations
First identify the steps done to construct an equation; the equation is then solved by ‘undoing’ these steps. This is achieved by doing ‘the opposite’ in ‘reverse order’. e.g.: Solve 3x + 4 = 16 for x. Note that x has been multiplied by 3 and then 4 has been added. Subtract 4 from both sides:
3x = 12
Divide both sides by 3:
x=4
⌅ An equation that states a relationship between two or more quantities is called a formula;
e.g. the area of a circle is given by A = ⇡r2 . The value of A, the subject of the formula, may be found by substituting a given value of r and the value of ⇡. A formula can be transposed to make a di↵erent variable the subject by using a similar procedure to solving linear equations, i.e. whatever has been done to the variable required is ‘undone’. ⌅ A literal equation is solved using the same techniques as for a numerical equation: transpose the literal equation to make the required variable the subject.
Technology-free questions 1
Simplify the following: a (x3 )4
b (y
3 12 4 )
2
Express the product 32 ⇥ 1011 ⇥ 12 ⇥ 10
3
Simplify the following: 3x y 2x a + 5 10 5 d
4
3 4 + x+2 x+4
Simplify the following: x+5 x2 + 5x a ÷ 2x 6 4x 12 c
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x2 4 3x 9 9 ⇥ ÷ x 3 x+2 x+2
4
3
c 3x 2 ⇥ 5x4 5
d (x3 ) 3 ⇥ x
5
in standard form.
b
4 x
7 y
e
5x 4x + x+4 x 2
c 5 2
f
5 2 + x+2 x 1 3 x
6 2
(x
b
3x 12x2 ÷ 2 x + 4 x 16
d
4x + 20 6x2 2 ⇥ ÷ 9x 6 x + 5 3x 2
2)2
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Review
34
Chapter 1: Algebra I
5
The human body can produce 2.5 million red blood cells per second. If a person donates 500 mL of blood, how long will it take to replace the red blood cells if a litre of blood contains 5 ⇥ 1012 red blood cells?
6
The Sun is approximately 1.5 ⇥ 108 km from Earth and a comet is approximately 3 ⇥ 106 km from Earth. How many times further from Earth than the comet is the Sun?
7
Swifts Creek Soccer Team has played 54 matches over the past three seasons. They have drawn one-third of their games and won twice as many games as they have lost. How many games have they lost?
8
A music store specialises in three types of CDs: classical, blues and heavy metal. In one week they sold a total of 420 CDs. They sold 10% more classical than blues, while sales of heavy metal CDs constituted 50% more than the combined sales of classical and blues CDs. How many of each type of CD did they sell?
9
The volume, V, of a cylinder is given by the formula V = ⇡r2 h, where r is the radius of the base and h is the height of the cylinder. a Find the volume of a cylinder with base radius 5 cm and height 12 cm. b Transpose the formula to make h the subject and hence find the height of a cylinder with a base radius of 5 cm and a volume of 585 cm3 . c Transpose the formula to make r the subject and hence find the radius of a cylinder with a height of 6 cm and a volume of 768 cm3 .
10
Solve for x:
a b + =c x x a dx ax + d d +b= d b
a xy + ax = b c 11
b
x x = +2 a b
Simplify: q p a + p+q p q c
x2 + x 6 2x2 + x 1 ⇥ x+1 x+3
b
1 x
2y
d
2a 2ab + b2 ⇥ 2a + b ba2
xy
y2
12
A is three times as old as B. In three years’ time, B will be three times as old as C. In fifteen years’ time, A will be three times as old as C. What are their present ages?
13
a Solve the following simultaneous equations for a and b: 1 1 a 5 = (b + 3) b 12 = (4a 2) 7 5 b Solve the following simultaneous equations for x and y: (p
q)x + (p + q)y = (p + q)2 qx
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
py = q2
pq
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Chapter 1 review
35
A man has to travel 50 km in 4 hours. He does it by walking the first 7 km at x km/h, cycling the next 7 km at 4x km/h and motoring the remainder at (6x + 3) km/h. Find x.
15
Simplify each of the following: a 2n2 ⇥ 6nk2 ÷ (3n)
16
Solve the equation
b
x+5 15
x
5 10
=1+
1 8c2 x3 y 2 xy ÷ 2 3 3 6a b c 15abc2
Review
14
2x . 15
Multiple-choice questions 1
For non-zero values of x and y, if 5x + 2y = 0, then the ratio 5 2
A
B
2 5
C
2 5
y is equal to x
D 1
E
5 4
2
The solution of the simultaneous equations 3x + 2y = 36 and 3x y = 12 is 20 A x= , y=8 B x = 2, y = 0 C x = 1, y = 3 3 20 3 3 D x= , y=6 E x= , y= 3 2 2
3
The solution of the equation t 9 = 3t 17 is 11 A t= 4 B t= C t=4 2 n p If m = , then p = n+ p n(1 m) n(m 1) n(1 + m) A B C 1+m 1+m 1 m
4
5
3 x
3
2 = x+3
A 1 6
7
x + 15 x2 9
9x2 y3 ÷ (15(xy)3 ) is equal to 9x 18xy A B 15 5
C
C
15 x
9
3y 5x
1 h(` + w) gives ` = 3 3V 2w w C h
E t= 2
D
n(1 + m) m 1
E
m(n 1) m+1
D
x+3 x2 9
E
1 9
D
3x 5
E
3 5x
D
3Vh 2
E
1 h(V + w) 3
D
9 6 6 x y 2
E
9 2 4 x y 2
Transposing the formula V = A
8
B
D t=2
hw 3V
(3x2 y3 )2 = 2x2 y 9 A x 2 y7 2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
B
3V h
B
9 2 5 x y 2
C
9 6 7 x y 2
w
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Review
36
Chapter 1: Algebra I
9
If X is 50% greater than Y and Y is 20% less than Z, then A X is 30% greater than Z D X is 10% less than Z
10
B X is 20% greater than Z E X is 10% greater than Z
C X is 20% less than Z
The average of two numbers is 5x + 4. One of the numbers is x. The other number is A 4x + 4
B 9x + 8
C 9x + 4
D 10x + 8
E 3x + 1
Extended-response questions 1
Jack cycles home from work, a distance of 10x km. Benny leaves at the same time and drives the 40x km to his home. a Write an expression in terms of x for the time taken for Jack to reach home if he cycles at an average speed of 8 km/h. b Write an expression in terms of x for the time taken for Benny to reach home if he drives at an average speed of 70 km/h. c In terms of x, find the di↵erence in times of the two journeys. d If Jack and Benny arrive at their homes 30 minutes apart: i find x, correct to three decimal places ii find the distance from work of each home, correct to the nearest kilometre.
2
Sam’s plastic dinghy has sprung a leak and water is pouring in the hole at a rate of 27 000 cm3 per minute. He grabs a cup and frantically starts bailing the water out at a rate of 9000 cm3 per minute. The dinghy is shaped like a circular prism (cylinder) with a base radius of 40 cm and a height of 30 cm. a How fast is the dinghy filling with water? b Write an equation showing the volume of water, V cm3 , in the dinghy after t minutes. c Find an expression for the depth of water, h cm, in the dinghy after t minutes. d If Sam is rescued after 9 minutes, is this before or after the dinghy has completely filled with water?
3
Henry and Thomas Wong collect basketball cards. Henry has five-sixths the number of cards that Thomas has. The Wright family also collect cards. George Wright has half as many cards again as Thomas, Sally Wright has 18 fewer than Thomas, and Zeb Wright has one-third the number Thomas has. a Write an expression for each child’s number of cards in terms of the number Thomas has. b The Wright family owns six more cards than the Wong family. Write an equation representing this information. c Solve the equation from part b and use the result to find the number of cards each child has collected.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Chapter 1 review
The gravitational force between two objects, F N, is given by the formula 6.67 ⇥ 10 11 m1 m2 r2 where m1 and m2 are the masses (in kilograms) of the two objects and r is the distance (in metres) between them. F=
Review
4
37
a What is the gravitational force between two objects each weighing 200 kg if they are 12 m apart? Express the answer in standard form (to two significant figures). b Transpose the above formula to make m1 the subject. c The gravitational force between a planet and an object 6.4 ⇥ 106 m away from the centre of the planet is found to be 2.4 ⇥ 104 N. If the object has a mass of 1500 kg, calculate the approximate mass of the planet, giving the answer in standard form (to two significant figures). 5
A water storage reservoir is 3 km wide, 6 km long and 30 m deep. (The water storage reservoir is assumed to be a cuboid.) a Write an equation to show the volume of water, V m3 , in the reservoir when it is d metres full. b Calculate the volume of water, VF m3 , in the reservoir when it is completely filled. The water flows from the reservoir down a long pipe to a hydro-electric power station in a valley below. The amount of energy, E J, that can be obtained from a full reservoir is given by the formula E = kVF h where k is a constant and h m is the length of the pipe. c Find k, given that E = 1.06 ⇥ 1015 when h = 200, expressing the answer in standard form correct to three significant figures. d How much energy could be obtained from a full reservoir if the pipe was 250 m long? e If the rate of water falling through the pipe is 5.2 m3 /s, how many days without rain could the station operate before emptying an initially full reservoir?
6
A new advertising symbol is to consist of three concentric circles as shown, with the outer circle having a radius of 10 cm. It is desired that the three coloured regions cover the same area. Find the radius of the innermost circle in the figure shown.
Yellow Blue Red
7
Temperatures in Fahrenheit (F) can be converted to Celsius (C) by the formula 5 C = (F 32) 9 Find the temperature which has the same numerical value in both scales.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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Review
38
Chapter 1: Algebra I
8
A cyclist goes up a long slope at a constant speed of 15 km/h. He turns around and comes down the slope at a constant speed of 40 km/h. Find his average speed over a full circuit.
9
A container has a cylindrical base and a hemispherical top, as shown in the figure. The height of the container is 20 cm and its capacity is to be exactly 2 litres. Let r cm be the radius of the base.
20 cm
a Express the height of the cylinder, h cm, in terms of r. b i Express the volume of the container in terms of r. ii Find r and h if the volume is 2 litres.
r cm
10
a Two bottles contain mixtures of wine and water. In bottle A there is two times as much wine as water. In bottle B there is five times as much water as wine. Bottle A and bottle B are used to fill a third bottle, which has a capacity of 1 litre. How much liquid must be taken from each of bottle A and bottle B if the third bottle is to contain equal amounts of wine and water? b Repeat for the situation where the ratio of wine to water in bottle A is 1 : 2 and the ratio of wine to water in bottle B is 3 : 1. c Generalise the result for the ratio m : n in bottle A and p : q in bottle B.
11
A cylinder is placed so as to fit into a cone as shown in the diagram. The cone has a height of 20 cm and a base radius of 10 cm. The cylinder has a height of h cm and a base radius of r cm.
20 cm h cm
r cm
a Use similar triangles to find h in terms of r. b The volume of the cylinder is given by the formula V = πr2 h. Find the volume of the cylinder in terms of r. c Use a CAS calculator to find the values of r and h for which the volume of the cylinder is 500 cm3 .
r cm
20 cm h cm
10 cm
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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Chapter 2
2
Number systems and sets
Objectives ! !
To understand and use set notation, including the symbols ∈, ⊆, ∪, ∩, ∅ and ξ.
! !
To interpret subsets of the real numbers defined using the modulus function.
To be able to identify sets of numbers, including the natural numbers, integers, rational numbers, irrational numbers and real numbers. To know and apply the rules for working with surds, including: ◃ simplification of surds ◃ rationalisation of surds.
!
To know and apply the definitions of factor, prime, highest common factor and lowest common multiple.
! !
To be able to solve linear Diophantine equations. To be able to solve problems with sets.
This chapter introduces set notation and discusses sets of numbers and their properties. Set notation is used widely in mathematics and in this book it is employed where appropriate. In this chapter we discuss natural numbers, integers and rational numbers, and then continue on to consider irrational numbers. √ Irrational numbers such as 2 naturally arise when applying Pythagoras’ theorem. When solving a quadratic equation, using the method of completing the square or the quadratic √ formula, we obtain answers such as x = 12 (1 ± 5). These numbers involve surds.
Since these numbers are irrational, we cannot express them in exact form using decimals or fractions. Sometimes we may wish to approximate them using decimals, but mostly we prefer to leave them in exact form. Thus we need to be able to manipulate these types of numbers and to simplify combinations of them which arise when solving a problem.
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40
Chapter 2: Number systems and sets
2A Set notation A set is a general name for any collection of things or numbers. There must be a way of deciding whether any particular object is a member of the set or not. This may be done by referring to a list of the members of the set or a statement describing them. For example: A = { 3, 3} = { x : x2 = 9 }
Note: { x : . . . } is read as ‘the set of all x such that . . . ’.
⌅ The symbol 2 means ‘is a member of’ or ‘is an element of’.
For example: 3 2 {prime numbers} is read ‘3 is a member of the set of prime numbers’.
⌅ The symbol < means ‘is not a member of’ or ‘is not an element of’.
For example: 4 < {prime numbers} is read ‘4 is not a member of the set of prime numbers’.
⌅ Two sets are equal if they contain exactly the same elements, not necessarily in the same
order. For example: if A = {prime numbers less than 10} and B = {2, 3, 5, 7}, then A = B.
⌅ The set with no elements is called the empty set and is denoted by ?.
⌅ The universal set will be denoted by ⇠. The universal set is the set of all elements which
are being considered. ⌅ If all the elements of a set B are also elements of a set A, then the set B is called a
subset of A. This is written B ✓ A. For example: {a, b, c} ✓ {a, b, c, d, e, f , g} and {3, 9, 27} ✓ {multiples of 3}. We note also that A ✓ A and ? ✓ A.
Venn diagrams are used to illustrate sets. For example, the diagram on the right shows two subsets A and B of a universal set ⇠ such that A and B have no elements in common. Two such sets are said to be disjoint.
ξ
A
B
I The union of two sets The set of all the elements that are members of set A or set B (or both) is called the union of A and B. The union of A and B is written A [ B.
Example 1 Let ⇠ = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, A = {1, 2, 3} and B = {1, 2, 9, 10}. Find A [ B and illustrate on a Venn diagram. Solution A [ B = {1, 2, 3, 9, 10}
The shaded area illustrates A [ B.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
ξ
4
A
5 3
6 1 2
7
8 9 10
B
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2A Set notation
41
I The intersection of two sets The set of all the elements that are members of both set A and set B is called the intersection of A and B. The intersection of A and B is written A \ B.
Example 2 Let ⇠ = {prime numbers less than 40}, A = {3, 5, 7, 11} and B = {3, 7, 29, 37}. Find A \ B and illustrate on a Venn diagram. Solution A \ B = {3, 7}
ξ
The shaded area illustrates A \ B.
2
17
A
5 11
19
23 3 7
31 29 37
13 B
I The complement of a set The complement of a set A is the set of all elements of ⇠ that are not members of A. The complement of A is denoted by A0 . If ⇠ = {students at Highland Secondary College} and A = {students with blue eyes}, then A0 is the set of all students at Highland Secondary College who do not have blue eyes. Similarly, if ⇠ = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10} and A = {1, 3, 5, 7, 9}, then A0 = {2, 4, 6, 8, 10}.
Example 3 Let ⇠ = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10}
A = {odd numbers} = {1, 3, 5, 7, 9} B = {multiples of 3} = {3, 6, 9}
a Show these sets on a Venn diagram. b Use the diagram to list the following sets: i A0
ii B0
iii A [ B
iv the complement of A [ B, i.e. (A [ B)0
v A0 \ B0
Solution a ξ
2
A
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
5
4
8
10
1
3 9
6
7
b From the diagram: B
i ii iii iv v
A0 = {2, 4, 6, 8, 10} B0 = {1, 2, 4, 5, 7, 8, 10} A [ B = {1, 3, 5, 6, 7, 9} (A [ B)0 = {2, 4, 8, 10} A0 \ B0 = {2, 4, 8, 10}
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42
2A
Chapter 2: Number systems and sets
I Finite and infinite sets When all the elements of a set may be counted, the set is called a finite set. For example, the set A = {months of the year} is finite. The number of elements of a set A will be denoted |A|. In this example, |A| = 12. If C = {letters of the alphabet}, then |C| = 26.
Sets which are not finite are called infinite sets. For example, the set of real numbers, R, and the set of integers, Z, are infinite sets.
Section summary ⌅ If x is an element of a set A, we write x 2 A.
⌅ If x is not an element of a set A, we write x < A. ⌅ The empty set is denoted by ? and the universal set by ⇠. ⌅ If every element of B is an element of A, we say B is a subset of A and write B ✓ A.
⌅ The set A [ B is the union of A and B, where x 2 A [ B if and only if x 2 A or x 2 B. ⌅ The set A \ B is the intersection of A and B, where x 2 A \ B if and only if x 2 A
and x 2 B. ⌅ The complement of A, denoted by A0 , is the set of all elements of ⇠ that are not in A. ⌅ If two sets A and B have no elements in common, we say that they are disjoint and write A \ B = ?.
Exercise 2A Example 1
1
Let ⇠ = {1, 2, 3, 4, 5}, A = {1, 2, 3, 5} and B = {2, 4}. Show these sets on a Venn diagram and use the diagram to find: a A0
Example 2
2
3
e A0 \ B0
b Q0
c P[Q
d (P [ Q)0
e P0 \ Q 0
b B0
c A[B
d (A [ B)0
e A0 \ B0
Let ⇠ = {natural numbers from 10 to 25}, P = {multiples of 4} and Q = {multiples of 5}. Show these sets on a Venn diagram and use this diagram to list the sets: a P0
5
d (A [ B)0
Let ⇠ = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12}, A = {multiples of 4} and B = {even numbers}. Show these sets on a Venn diagram and use this diagram to list the sets: a A0
4
c A[B
Let ⇠ = {natural numbers less than 17}, P = {multiples of 3} and Q = {even numbers}. Show these sets on a Venn diagram and use it to find: a P0
Example 3
b B0
b Q0
c P[Q
d (P [ Q)0
e P0 \ Q 0
Let ⇠ = {p, q, r, s, t, u, v, w}, X = {r, s, t, w} and Y = {q, s, t, u, v}. Show ⇠, X and Y on a Venn diagram, entering all members. Hence list the sets: a X0
b Y0
Which two sets are equal? Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
c X0 \ Y 0
d X0 [ Y 0
e X[Y
f (X [ Y)0
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2A
43
2B Sets of numbers
6 Let ξ = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12}, X = {factors of 12} and Y = {even numbers}. Show ξ, X and Y on a Venn diagram, entering all members. Hence list the sets: a X′
b Y′
Which two sets are equal?
c X′ ∪ Y ′
7 Draw this diagram six times. Use shading to illustrate each of the following sets: a A′ d A′ ∪ B′
b B′ e A∪B
d (X ∩ Y)′
e X∪Y
f (X ∪ Y)′
ξ
A
c A′ ∩ B′ f (A ∪ B)′
B
8 Let ξ = {different letters in the word GENERAL}, A = {different letters in the word ANGEL}, B = {different letters in the word LEAN}
Show these sets on a Venn diagram and use this diagram to list the sets: a A′
b B′
c A∩B
d A∪B
e (A ∪ B)′
f A′ ∪ B′
9 Let ξ = {different letters in the word MATHEMATICS} A = {different letters in the word ATTIC}
B = {different letters in the word TASTE}
Show ξ, A and B on a Venn diagram, entering all the elements. Hence list the sets: a A′
b B′
c A∩B
d (A ∪ B)′
e A′ ∪ B′
f A′ ∩ B′
2B Sets of numbers Recall that the elements of {1, 2, 3, 4, . . . } are called natural numbers, and the elements of { . . . , −2, −1, 0, 1, 2, . . . } are called integers. p The numbers of the form , with p and q integers, q ! 0, are called rational numbers. q The real numbers which are not rational are called irrational. Some examples of irrational √ √ √ √ p numbers are 2, 3, π, π + 2 and 6 + 7. These numbers cannot be written in the form , q for integers p, q; the decimal representations of these numbers do not terminate or repeat. ! The set of real numbers is denoted by R. ! The set of rational numbers is denoted
by Q. ! The set of integers is denoted by Z. ! The set of natural numbers is denoted by N. It is clear that N ⊆ Z ⊆ Q ⊆ R, and this may be represented by the diagram on the right. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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44
Chapter 2: Number systems and sets
We can use set notation to describe subsets of the real numbers. For example: ⌅ { x : 0 < x < 1 } is the set of all real numbers strictly between 0 and 1 ⌅ { x : x > 0, x 2 Q } is the set of all positive rational numbers
⌅ { 2n : n = 0, 1, 2, . . . } is the set of all non-negative even numbers.
The set of all ordered pairs of real numbers is denoted by R2 . That is, R2 = { (x, y) : x, y 2 R }
This set is known as the Cartesian product of R with itself.
I Rational numbers Every rational number can be expressed as a terminating or recurring decimal. To find the decimal representation of a rational number
m , perform the division m ÷ n. n
3 For example, to find the decimal representation of , divide 3.0000000 . . . by 7. 7 0. 4 2 8 5 7 1 4 . . . 7 3. 3 0 2 0 6 0 4 0 5 0 1 0 3 0 . . . Therefore
3 ˙ ˙ = 0.42857 1. 7
Theorem
Every rational number can be written as a terminating or recurring decimal. Proof Consider any two natural numbers m and n. At each step in the division of m by n, there is a remainder. If the remainder is 0, then the division algorithm stops and the decimal is a terminating decimal. If the remainder is never 0, then it must be one of the numbers 1, 2, 3, . . . , n 1. (In the above example, n = 7 and the remainders can only be 1, 2, 3, 4, 5 and 6.) Hence the remainder must repeat after at most n 1 steps. Further examples: 1 1 = 0.5, = 0.2, 2 5
1 = 0.1, 10
1 ˙ = 0.3, 3
1 ˙ = 0.14285 7˙ 7
Theorem
A real number has a terminating decimal representation if and only if it can be written as m 2↵ ⇥ 5 for some m 2 Z and some ↵, 2 N [ {0}.
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2B Sets of numbers
Proof Assume that x = by 5↵ . Then x=
m with ↵ 2↵ ⇥ 5
45
. Multiply the numerator and denominator
m ⇥ 5↵ m ⇥ 5↵ = 2↵ ⇥ 5↵ 10↵
and so x can be written as a terminating decimal. The case ↵
Probability > Random > Seed and enter
the last 4 digits of your phone number. This ensures that your random-number starting point di↵ers from the calculator default. ⌅ For a random number between 0 and 1, use Menu > Probability > Random > Number. ⌅ For a random integer, use Menu > Probability > Random > Integer. To obtain five random integers between 2 and 4 inclusive, use the command randInt(2, 4, 5) as shown.
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350 Chapter 12: Sampling and sampling distributions Using the Casio ClassPad ⌅ In M, press the Keyboard button. ⌅ Find and then select
Catalog by first tapping H at the bottom of the left sidebar. ⌅ Scroll across the alphabet to the letter R.
⌅ To generate a random number between 0 and 1: • In Catalog , select rand(. • Tap
EXE .
⌅ To generate three random integers between 1 and 6
inclusive: • In Catalog , select rand(. • Type: 1, 6) • Tap EXE three times. ⌅ To generate a list of 10 random numbers between 0 and 1: • In Catalog , select randList(. Type: 10) • Tap EXE and then tap I to view all the numbers. ⌅ To generate a list of 20 random integers between 1 and 30 inclusive: • In Catalog , select randList(. Type: 20, 1, 30) • Tap EXE and then tap I to view all the integers.
Example 2 Consider the population of Year 12 students at ABC Secondary College given in the table, which shows the sex and IQ score for each of the 50 students (25 males and 25 females). Each student has been given an identity number (Id). Use a random number generator to select a random sample of size 5 from this population. Id
Sex
IQ
Id
Sex
IQ
Id
Sex
IQ
Id
Sex
IQ
Id
Sex
IQ
1 2 3 4 5 6 7 8 9 10
F M M M F F F M M M
105 111 104 93 92 99 88 107 97 88
11 12 13 14 15 16 17 18 19 20
F F F M F F M M M F
103 97 122 101 84 108 95 88 95 86
21 22 23 24 25 26 27 28 29 30
M M M M F F F F M M
95 113 108 106 95 86 87 134 118 58
31 32 33 34 35 36 37 38 39 40
F M M F F M F M F F
68 113 87 93 100 114 119 100 100 114
41 42 43 44 45 46 47 48 49 50
M M F M M F F M F F
79 106 118 98 113 120 93 81 114 107
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12A Populations and samples 351
Solution Generating five random integers from 1 to 50 gives on this occasion: 5, 1, 42, 16, 32. Thus the sample chosen consists of the students listed in the table on the right.
Id
Sex
IQ
1 5 16 32 42
F F F M M
105 92 108 113 106
I Population parameters and sample statistics There are 25 females and 25 males in the population of Year 12 students at ABC Secondary College, and therefore the proportion of females in the population is 0.5. This is called the population proportion and is generally denoted by p. Population proportion p =
number in population with attribute population size
3 For the sample chosen in Example 2, the proportion of females in the sample is = 0.6. This 5 value is called the sample proportion and is denoted by p. ˆ (We say ‘p hat’.) Sample proportion pˆ =
number in sample with attribute sample size
In this particular case, pˆ = 0.6, which is not the same as the population proportion p = 0.5. This does not mean there is a problem. In fact, each time a sample is selected the number of females in the sample will vary. Now consider the IQ scores of the Year 12 students at ABC Secondary College. The mean IQ for the whole population is 100.0. This is called the population mean and is generally denoted by the Greek letter µ (pronounced mu). Population mean µ =
sum of the data values in the population population size
The mean IQ for the sample chosen in Example 2 is 105 + 92 + 108 + 113 + 106 = 104.8 5 This value is called the sample mean and is denoted by x¯. (We say ‘x bar’.) Sample mean x¯ =
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sum of the data values in the sample sample size
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352 Chapter 12: Sampling and sampling distributions
12A
In this particular case, the value of the sample mean x¯ (104.8) is not the same as the value of the population mean µ (100.0). As before, the IQ scores will vary from sample to sample. ⌅ The population proportion p and the population mean µ are population parameters;
their values are constant for a given population. ⌅ The sample proportion pˆ and the sample mean x¯ are sample statistics; their values are not constant, but vary from sample to sample.
Section summary ⌅ A population is the set of all eligible members of a group which we intend to study. ⌅ A sample is a subset of the population which we select in order to make inferences
⌅ ⌅ ⌅ ⌅ ⌅
about the population. Generalising from the sample to the population will not be useful unless the sample is representative of the population. The simplest way to obtain a valid sample is to choose a random sample, where every member of the population has an equal chance of being included in the sample. The population proportion p is the proportion of individuals in the entire population possessing a particular attribute, and is constant for a given population. The sample proportion pˆ is the proportion of individuals in a particular sample possessing this attribute, and varies from sample to sample. The population mean µ is the mean of all values of a measure in the entire population, and is constant for a given population. The sample mean x¯ is the mean of the values of this measure in a particular sample, and varies from sample to sample.
Exercise 12A Example 1
1
In order to estimate the proportion of students in the state who use the internet for learning purposes, a researcher conducted an email poll. She found that 83% of those surveyed use the internet for learning purposes. Do you think that this is an appropriate way of selecting a random sample of students? Explain your answer.
2
A market researcher wishes to determine the age profile of the customers of a popular fast-food chain. She positions herself outside one of the restaurants between 4 p.m. and 8 p.m. one weekend, and asks customers to fill out a short questionnaire. Do you think this sample will be representative of the population? Explain your answer.
3
To measure support for the current Prime Minister, a television station conducts a phone-in poll, where viewers are asked to telephone one number if they support the Prime Minister and another number if they do not. Is this an appropriate method of choosing a random sample? Give reasons for your answer.
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12B The distribution of the sample proportion 353
12A Example 2
4
a Use a random number generator to select a random sample of size 5 from the population of Year 12 students at ABC Secondary College given in Example 2. b Determine the proportion of females in your sample. c Determine the mean IQ of the students in your sample.
5
Of a random sample of 100 homes, 48 were found to have one or more pet dogs. a What proportion of these homes have one or more pet dogs? b Is this the value of the population proportion p or the sample proportion p? ˆ
6
In a certain school, 42% of the students travel to school by public transport. A group of 100 students were selected in a random sample, and 37 of them travel to school by public transport. In this example: a What is the population? b What is the value of the population proportion p? c What is the value of the sample proportion p? ˆ
7
Recent research has established that Australian adults spend on average four hours per day on sedentary leisure activities such as watching television. A group of 100 people were selected at random and found to spend an average of 3.5 hours per day on sedentary leisure activities. In this example: a What is the population? b What is the value of the population mean µ? c What is the value of the sample mean x¯?
12B The distribution of the sample proportion We have seen that the sample proportion is not constant, but varies from sample to sample. In this section we will look more closely at this variation in the sample proportion and, in particular, at the values which it might be expected to take. In order to do this, we need to introduce some further concepts in probability.
I Random variables Consider the sample space obtained when a coin is tossed three times: " = {HHH, HHT, HTH, THH, HTT, THT, TTH, TTT}
Suppose we are particularly interested in the number of heads associated with each outcome. We let X represent the number of heads observed when a coin is tossed three times. Then each outcome in the sample space can be associated with a value of X, as shown in the following table.
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354 Chapter 12: Sampling and sampling distributions Outcome
Number of heads
HHH
X=3
HHT
X=2
HTH
X=2
THH
X=2
HTT
X=1
THT
X=1
TTH
X=1
TTT
X=0
From the table we can see that the possible values of X are 0, 1, 2 and 3. Since the actual value that X will take is the result of a random experiment, X is called a random variable. A random variable can be discrete or continuous: ⌅ A discrete random variable is one which may take on only a countable number of
distinct values, such as 0, 1, 2, 3, 4. Discrete random variables are usually (but not necessarily) generated by counting. The number of children in a family, the number of brown eggs in a carton of a dozen eggs, and the number of times we roll a die before we observe a ‘six’ are all examples of discrete random variables. ⌅ A continuous random variable is one that can take any value in an interval of the real number line, and is usually (but not always) generated by measuring. Height, weight, and the time taken to complete a puzzle are all examples of continuous random variables.
Discrete probability distributions Because the values of a random variable are associated with outcomes in the sample space, we can determine the probability of each value of the random variable occurring. Let’s look again at the results obtained when a coin is tossed three times. Assuming that the coin is fair, we can add probabilities to the previous table.
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Outcome
Number of heads
Probability
HHH
X=3
1 8
HHT
X=2
1 8
HTH
X=2
1 8
THH
X=2
1 8
HTT
X=1
1 8
THT
X=1
1 8
TTH
X=1
1 8
TTT
X=0
1 8
Pr(X = 3) =
1 8
Pr(X = 2) =
3 8
Pr(X = 1) =
3 8
Pr(X = 0) =
1 8
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12B The distribution of the sample proportion 355
The list of all possible values of the random variable X, together with the probability associated with each value, is known as the probability distribution of X. More usually, we would summarise the probability distribution associated with the number of heads observed when a fair coin is tossed three times in a table as follows. x
0
1
2
3
Pr(X = x)
1 8
3 8
3 8
1 8
Note that, since every possible value of the random variable is included, the probabilities must add to 1. The probability distribution of a discrete random variable X is a function p(x) = Pr(X = x) that assigns a probability to each value of X. It can be represented by a rule, a table or a graph, and must give a probability p(x) for every value x that X can take. For any discrete probability distribution, the following must be true: ⌅ 0 p(x) 1, for every value x that X can take. ⌅ The sum of the values of p(x) must be 1.
To determine the probability that X lies in a given interval, we add together the probabilities that X takes each value included in that interval, as shown in the following example.
Example 3 Consider the probability distribution: x Pr(X = x)
1
2
3
4
5
6
0.2
0.3
0.1
0.2
0.15
0.05
Use the table to find: a Pr(X = 3)
b Pr(X < 3)
c Pr(X
4)
d Pr(3 X 5)
e Pr(X , 5)
Solution a Pr(X = 3) = 0.1
Explanation
b Pr(X < 3) = 0.2 + 0.3 = 0.5
If X is less than 3, then from the table we see that X can take the value 1 or 2.
c Pr(X
If X is greater than or equal to 4, then X can take the value 4, 5 or 6.
4) = 0.2 + 0.15 + 0.05 = 0.4
d Pr(3 X 5) = 0.1 + 0.2 + 0.15 = 0.45
Here X can take the value 3, 4 or 5.
e Pr(X , 5) = 1
The sum of all the probabilities must be 1.
=1
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Pr(X = 5) 0.15 = 0.85
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356 Chapter 12: Sampling and sampling distributions
I The sample proportion as a random variable Since pˆ varies according to the contents of the random samples, we can consider the sample ˆ proportions pˆ as being the values of a random variable, which we will denote by P. As Pˆ is a random variable, it can be described by a probability distribution. The distribution of a statistic which is calculated from a sample (such as the sample proportion) has a special name – it is called a sampling distribution.
Sampling from a small population Suppose we have a bag containing six blue balls and four red balls, and from the bag we take a sample of size 4. We are interested in the proportion of blue balls in the sample. We know 6 that the population proportion is equal to . That is, 10 p = 0.6 The probabilities associated with the possible values of the sample proportion pˆ can be calculated using our knowledge of combinations. Recall that ! n n! = x x! (n x)!
is the number of di↵erent ways to choose x objects from n objects. This notation is read as ‘n choose x’.
Example 4 A bag contains six blue balls and four red balls, and a random sample of size 4 is drawn. Find the probability that there is one blue ball in the sample. That is, find Pr(Pˆ = 0.25). Solution ! 10 In total, there are = 210 ways to select 4 balls from 10 balls. 4 ! ! 6 4 There are = 6 ways to select 1 blue ball from 6 blue balls, and there are = 4 ways 1 3 to select 3 red balls from 4 red balls. Thus the probability of obtaining 1 blue ball and 3 red balls is ⇣6⌘ ⇣4⌘ 24 1 ⇥ 3 Pr(Pˆ = 0.25) = ⇣10⌘ = 210 4
This is an example of the hypergeometric distribution, which applies in the following circumstances: ⌅ We have a population of N objects, and each object can be considered as either a defective
or a non-defective. There is a total of D defectives in the population. ⌅ We will choose, without replacement, a sample of size n from the population, and the random variable of interest X is the number of defectives in the sample. Note: There does not have to be anything wrong with an object classified as ‘defective’ – this
distribution just happened to arise in a context where this terminology made sense. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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12B The distribution of the sample proportion 357 Hypergeometric distribution
The probability of obtaining x defectives in a sample of size n for a hypergeometric random variable X is ! ! D N D x n x ! Pr(X = x) = for x = 0, 1, 2, . . . , min(n, D) N n
where N is the size of the population and D is the number of defectives in the population. Note: There cannot be more defectives in the sample than in the population, nor more than
the sample size, and so the upper limit on the values of X is determined by D and n. Continuing with our example, we let X denote the number of blue balls in a sample of size 4. We can now use the formula for the hypergeometric distribution to find the probabilities of ˆ For example: values of P. ⇣6⌘ ⇣4⌘ 90 2 2 Pr(Pˆ = 0.5) = Pr(X = 2) = ⇣10⌘ = 210 4
The following table gives the probability of obtaining each possible sample proportion pˆ when selecting a random sample of size 4 from the bag. Number of blue balls in the sample, x
0
1
2
3
4
Proportion of blue balls in the sample, pˆ
0
0.25
0.5
0.75
1
1 210
24 210
90 210
80 210
15 210
Probability
The possible values of pˆ and their associated probabilities together form a probability ˆ which can summarised as follows: distribution for the random variable P, pˆ Pr(Pˆ = p) ˆ
0
0.25
0.5
0.75
1
1 210
24 210
90 210
80 210
15 210
Example 5 A bag contains six blue balls and four red balls, and a random sample of size 4 is drawn (without replacement). Use the sampling distribution in the previous table to determine the probability that the proportion of blue balls in the sample is more than 0.25. Solution Pr(Pˆ > 0.25) = Pr(Pˆ = 0.5) + Pr(Pˆ = 0.75) + Pr(Pˆ = 1) =
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90 80 15 185 + + = 210 210 210 210
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358 Chapter 12: Sampling and sampling distributions Example 6 It is known that 80% of a group of 40 students have been immunised against measles. Use the hypergeometric distribution to find the sampling distribution of the sample proportion of immunised students if a random sample of 5 students is selected from this group. Solution Since 80% of the students have been immunised, there are 32 immunised students and 8 non-immunised students in the population. Let X be the number of immunised students in the sample. Then ⇣32⌘ ⇣8⌘ Pr(Pˆ = 0) = Pr(X = 0) =
0
5
⇣40⌘
= 0.000085
⇣32⌘ ⇣8⌘ ⇣40⌘
= 0.0034
⇣32⌘ ⇣8⌘ ⇣40⌘
= 0.0422
0
0.2
0.4
0.6
0.8
1
0.0001
0.0034
0.0422
0.2111
0.4372
0.3060
5
Pr(Pˆ = 0.2) = Pr(X = 1) =
1
4
5
Pr(Pˆ = 0.4) = Pr(X = 2) =
2
3
5
Continuing in this way, we obtain the following table for the sampling distribution (with probabilities given to four decimal places). pˆ Pr(Pˆ = p) ˆ
Sampling from a large population Generally, when we select a sample, it is from a population which is too large or too difficult to enumerate or even count – populations such as all the people in Australia, or all the cows in Texas, or all the people who will ever have asthma. When the population is so large, we assume that the probability of observing the attribute we are interested in remains constant with each selection, irrespective of prior selections for the sample. In such cases, we cannot use the hypergeometric distribution to determine the sampling ˆ Instead, we use another well-known discrete probability distribution – the distribution of P. binomial distribution – which applies in the following circumstances: ⌅ The experiment consists of a number, n, of identical trials. ⌅ Each trial results in one of two outcomes, either a success or a failure. ⌅ The probability of success on a single trial, p, is constant for all trials. ⌅ The trials are independent (so that the outcome of any trial is not a↵ected by the outcome
of any previous trial). Trials which meet these conditions are called Bernoulli trials, and the number of successes observed is then called a binomial random variable.
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12B The distribution of the sample proportion 359 Binomial distribution
The probability of achieving x successes in a sequence of n trials for a binomial random variable X is ! n x Pr(X = x) = p (1 p)n x for x = 0, 1, 2, . . . , n x where p is the probability of success on each trial.
⇣⌘ Proof There are nx di↵erent ways that x successes and n x failures can be ordered within the n trials, since we just have to choose x trials from n trials to be the successes. In each trial, the probability of success is p and the probability of failure is 1 p. Thus the probability of obtaining x successes and n x failures in a given order is p x (1 p)n x by the multiplication rule, since the trials are independent. ⇣⌘ The nx di↵erent orderings are mutually exclusive, and so we obtain the formula for Pr(X = x) using the addition rule. Suppose we know that 70% of all 17-year-olds in Australia attend school. That is, p = 0.7. We will assume that this probability remains constant for all selections for the sample. Now consider selecting a random sample of size 4 from the population of all 17-year-olds in Australia. The probabilities associated with each value of the sample proportion pˆ can be calculated using the binomial distribution: ! 4 Pr(X = x) = 0.7 x 0.34 x for x = 0, 1, 2, 3, 4 x These probabilities can be found easily using your calculator.
Using the TI-Nspire To find the values of Pr(X = x) for a binomial random variable X with n = 4 and p = 0.7: ⌅ Use menu > Probability > Distributions > Binomial Pdf and complete as shown. ⌅ Use
tab
or H to move between cells.
⌅ The result is as shown. Note: You can also type in the command and
the parameter values directly if preferred.
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360 Chapter 12: Sampling and sampling distributions Using the Casio ClassPad To find Pr(X = 3) for a binomial random variable X with n = 4 and p = 0.7: ⌅ In M, go to Interactive > Distribution > Discrete > binomialPDf. ⌅ Enter the number of successes and the parameters as shown. Tap
OK .
The following table gives the probability of obtaining each possible sample proportion pˆ when selecting a random sample of four 17-year-olds. Number at school in the sample, x
0
1
2
3
4
Proportion at school in the sample, pˆ
0
0.25
0.5
0.75
1
0.0081
0.0756
0.2646
0.4116
0.2401
Probability
Once again, we can summarise the sampling distribution of the sample proportion as follows: pˆ Pr(Pˆ = p) ˆ
0
0.25
0.5
0.75
1
0.0081
0.0756
0.2646
0.4116
0.2401
Note that the probabilities for the sample proportions, p, ˆ correspond to the probabilities for the numbers of successes, x. That is: Pr(Pˆ = 0) = Pr(X = 0) Pr(Pˆ = 34 ) = Pr(X = 3)
Pr(Pˆ = 41 ) = Pr(X = 1) Pr(Pˆ = 1) = Pr(X = 4)
Pr(Pˆ = 24 ) = Pr(X = 2)
Example 7 Use the sampling distribution in the previous table to determine the probability that, in a random sample of four Australian 17-year-olds, the proportion attending school is less than 50%. Solution Pr(Pˆ < 0.5) = Pr(Pˆ = 0) + Pr(Pˆ = 0.25) = 0.0081 + 0.0756 = 0.0837
Example 8 Suppose that 10% of the batteries produced by a particular production line are faulty. Use the binomial distribution to find the sampling distribution of the sample proportion of faulty batteries when a random sample of 3 batteries is selected from this production line.
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12B The distribution of the sample proportion 361
Solution Using the binomial distribution with n = 3 and p = 0.1: ! 3 ˆ Pr(P = 0) = Pr(X = 0) = (0.1)0 (0.9)3 = 0.729 0 ! 3 1 ˆ Pr(P = 3 ) = Pr(X = 1) = (0.1)1 (0.9)2 = 0.243 1 ! 3 Pr(Pˆ = 23 ) = Pr(X = 2) = (0.1)2 (0.9)1 = 0.027 2 ! 3 Pr(Pˆ = 1) = Pr(X = 3) = (0.1)3 (0.9)0 = 0.001 3
We can summarise the sampling distribution of the sample proportion as follows: pˆ Pr(Pˆ = p) ˆ
0
1 3
2 3
1
0.729
0.243
0.027
0.001
I Comparing the hypergeometric and binomial distributions Both the hypergeometric and the binomial distributions can be considered to arise from the process of sampling. ⌅ Hypergeometric distribution: describes situations where the sampling is taking place
without replacement, so that the probability of observing a particular outcome on any trial depends on the results of previous trials. ⌅ Binomial distribution: applies to sampling with replacement, or sampling from a population that is so large that it does not matter if it is with or without replacement. How large should the population be for sampling to be considered binomial? Consider a jar containing 50 black balls and 50 white balls (that is, a population of size 100). Suppose that three balls are selected at random from the jar, and define X to be the number of black balls in the sample. Then X is a binomial random variable if the selected ball is replaced between consecutive selections, and a hypergeometric random variable if it is not. Let’s look at the probability distribution for each of these situations. Without replacement: Hypergeometric (N = 100, D = 50, n = 3)
x Pr(X = x)
0
1
2
3
0.121
0.379
0.379
0.121
With replacement: Binomial (n = 3, p = 0.5)
x Pr(X = x)
0
1
2
3
0.125
0.375
0.375
0.125
We can see that the two probability distributions are very similar for this example. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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362 Chapter 12: Sampling and sampling distributions Whether it is appropriate to use the binomial distribution when sampling without replacement from a population this small (size 100) will also depend on the size of the sample. We have seen that when the sample is small (only 3), the approximation is quite good.
Example 9 Suppose that five students are selected at random from a population containing 50 male students and 50 female students, and that Pˆ is the random variable representing the ˆ proportion of females in the sample. Find the probability distribution of P: a exactly b assuming that the proportion of female students remains unchanged throughout the sampling process. Solution a Use the hypergeometric distribution with N = 100, D = 50 and n = 5: x
0
1
2
3
4
5
pˆ ˆ Pr(P = p) ˆ
0
0.2
0.4
0.6
0.8
1
0.0281
0.1529
0.3189
0.3189
0.1529
0.0281
b Use the binomial distribution with n = 5 and p = 0.5: x
0
1
2
3
4
5
pˆ
0
0.2
0.4
0.6
0.8
1
0.03125
0.15625
0.3125
0.3125
0.15625
0.03125
Pr(Pˆ = p) ˆ
Section summary ⌅ For a discrete random variable X, the probability distribution of X is a function
p(x) = Pr(X = x) that assigns a probability to each value of X. X ⌅ The sample proportion Pˆ = is a random variable, where X is the number of n favourable outcomes in a sample of size n. ⌅ The distribution of Pˆ is known as the sampling distribution of the sample proportion. ⌅ When the population is small, the sampling distribution of the sample proportion Pˆ can be determined using the hypergeometric distribution: The probability of obtaining x defectives in a sample of size n is given by ! ! D N D x n x ! Pr(X = x) = for x = 0, 1, 2, . . . , min(n, D) N n where N is the size of the population and D is the number of defectives in the population.
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12B The distribution of the sample proportion 363
12B
⌅ When the population is large, the sampling distribution of the sample proportion Pˆ
can be determined using the binomial distribution: The probability of achieving x successes in a sequence of n trials is given by ! n x Pr(X = x) = p (1 p)n x for x = 0, 1, 2, . . . , n x where p is the probability of success on each trial.
Exercise 12B Example 3
1
A biased coin is such that the probability of obtaining a head on any toss is 0.6. a Find the probability distribution of X, the number of heads observed when the coin is tossed twice. b Find Pr(X 1).
2
Samar has determined the following probability distribution for the number of cups of co↵ee, X, that he drinks in a day. x p(x)
1
2
3
4
5
6
0.05
0.15
0.35
0.25
0.15
0.05
Use the table to find: a Pr(X = 3) d Pr(1 < X < 5) Example 5
3
b Pr(X < 3) e Pr(X , 5)
The following table gives the sampling distribution of the sample proportion when a sample of size 5 is selected from a group of 40 students, 80% of whom have been immunised against measles. pˆ ˆ Pr(P = p) ˆ
0
0.2
0.4
0.6
0.8
1
0.0001
0.0034
0.0422
0.2111
0.4372
0.3060
Use the table to find: a Pr(Pˆ = 0.2) d Pr(0.2 < Pˆ < 0.8) Example 6
4
c Pr(X 4) f Pr(1 < X < 5 | X > 1)
b Pr(Pˆ < 0.4) e Pr(Pˆ < 0.8 | Pˆ > 0)
c Pr(Pˆ
0.8) f Pr(0.2 < Pˆ < 0.8 | Pˆ > 0.4)
A chocolate box contains eight soft-centred and eight hard-centred chocolates. a What is p, the proportion of soft-centred chocolates in the box? b Three chocolates are to be selected at random. What are the possible values of the sample proportion pˆ of soft-centred chocolates in the sample? c Use the hypergeometric distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of soft-centred chocolates when samples of size 3 are selected from the box. d Use the sampling distribution from c to determine the probability that the proportion of soft-centred chocolates in the sample is more than 0.25.
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364 Chapter 12: Sampling and sampling distributions 5
12B
A swimming club has 20 members: 12 males and 8 females. a What is p, the proportion of males in the swimming club? b A team of five swimmers is to be selected from the club at random. What are the possible values of the sample proportion pˆ of males on the team? c Use the hypergeometric distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of males on the team. d Use the sampling distribution from c to determine the probability that the proportion of males on the team is more than 0.7. e Find Pr(0 < Pˆ < 0.8) and hence find Pr(Pˆ < 0.8 | Pˆ > 0).
6
A random sample of four items is selected from a batch of 50 items which contains 15 defectives. a What is p, the proportion of defectives in the batch? b What are the possible values of the sample proportion pˆ of defectives in the sample? c Use the hypergeometric distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of defectives in the sample. d Use the sampling distribution from c to determine the probability that the proportion of defectives in the sample is more than 0.5. e Find Pr(0 < Pˆ < 0.5) and hence find Pr(Pˆ < 0.5 | Pˆ > 0).
Example 7
7
The following table gives the sampling distribution of the sample proportion of defectives in a random sample of 3 batteries from a particular production line. pˆ Pr(Pˆ = p) ˆ
0
1 3
2 3
1
0.729
0.243
0.027
0.001
a Use the table to determine the probability that the proportion of defectives in the sample is more than 0.6. b Find Pr(0 < Pˆ < 0.6) and hence find Pr(Pˆ < 0.6 | Pˆ > 0). Example 8
8
Suppose that a fair coin is tossed 10 times and the number of heads observed. a What is p, the probability that a head is observed when a fair coin is tossed? b What are the possible values of the sample proportion pˆ of heads in the sample? c Use the binomial distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of heads in the sample. d Use the sampling distribution from c to determine the probability that the proportion of heads in the sample is more than 0.5.
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12B The distribution of the sample proportion 365
12B 9
Suppose that the probability of a male child being born is 0.52. Of the next six children born at a maternity hospital: a What are the possible values of the sample proportion pˆ of male children born? b Use the binomial distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of male children born. c Use the sampling distribution from b to determine the probability that the proportion of male children born is less than 0.4. d Find Pr(Pˆ < 0.3 | Pˆ < 0.8).
10
Suppose that, in a certain country, the probability that a person is right-handed is 0.8. If eight people are selected at random from that country: a What are the possible values of the sample proportion pˆ of right-handed people in the sample? b Construct a probability distribution table which summarises the sampling distribution of the sample proportion of right-handed people in the sample. c Use the sampling distribution from b to determine the probability that the proportion of right-handed people in the sample is more than 0.6. d Find Pr(Pˆ > 0.6 | Pˆ > 0.25).
Example 9
11
Suppose that a population consists of 50 male and 50 female students, and that Pˆ is the random variable representing the proportion of females in a sample randomly chosen from this population. ˆ a If the sample size is 4, find the probability distribution of P: i exactly (using the hypergeometric distribution) ii assuming that the proportion of female students remains unchanged throughout the sampling process (using the binomial distribution). ˆ b If the sample size is 10, find the probability distribution of P: i exactly (using the hypergeometric distribution) ii assuming that the proportion of female students remains unchanged throughout the sampling process (using the binomial distribution). c Compare your answers to parts i and ii for each of the two sample sizes. What is the e↵ect of the increased sample size on the similarity of the answers obtained using the hypergeometric and binomial distributions?
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366 Chapter 12: Sampling and sampling distributions
12C Investigating the distribution of the sample proportion using simulation In the previous section, we used our knowledge of probability to investigate the distribution of the sample proportion for small samples. In this section we are going to use simulation to investigate the distribution of the sample proportion for larger samples.
I The shape of the distribution of the sample proportion Suppose, for example, we know that 55% of people in Australia have blue eyes (p = 0.55) and we are interested in the values of the sample proportion pˆ which might be observed when samples of size 100 are drawn at random from the population. If we select one sample of 100 people and find that 58 people have blue eyes, then the value 58 of the sample proportion is pˆ = = 0.58. 100 If a second sample of 100 people is selected and this time 63 people have blue eyes, then the 63 value of the sample proportion for this second sample is pˆ = = 0.63. 100 Continuing in this way, the values of pˆ obtained from 10 samples might look like those in the following dotplot. The proportion of people with blue eyes in the sample, p, ˆ is varying from sample to sample: from as low as 0.53 to as high as 0.65 for these particular 10 samples.
0.50
0.55
0.60
0.65
What does the distribution of the sample proportions look like if we continue with this sampling process? The following dotplot summarises the values of pˆ from 100 samples (each of size 100). We can see from the dotplot that the distribution is reasonably symmetric, centred at 0.55, and has values ranging from 0.43 to 0.68.
0.40
0.45
0.50
0.55
0.60
0.65
0.70
Example 10 A random sample of 100 people is drawn from a population in which 55% of people have blue eyes. Use the previous dotplot to estimate the probability that 65% or more of the people in the sample have blue eyes. Solution From the dotplot we can count 3 out of 100 samples where the sample proportion is 0.65 or more. Thus we can estimate 3 Pr(Pˆ 0.65) ⇡ = 0.03 100 Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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12C Investigating the distribution of the sample proportion using simulation 367
What does the distribution look like when 1000 samples (each of size 100) are chosen?
100 Frequency
80
This time, because of the amount of data, the distribution is presented as a histogram. We can see that the distribution is becoming smoother and more clearly symmetric about 0.55, with a similar spread as before.
We can see that the majority of values are concentrated in the central region close to 0.55, with relatively few values of the sample proportion pˆ that are less than 0.45 or more than 0.65.
40 20 0
Frequency
By the time we have taken 10 000 samples (each of size 100), the distribution is quite smooth and clearly symmetric about 0.55.
60
800 700 600 500 400 300 200 100 0
0.40 0.45 0.50 0.55 0.60 0.65 0.70
0.40 0.45 0.50 0.55 0.60 0.65 0.70
The number of simulations to use for a good picture of the distribution is somewhat arbitrary. We have seen here that more is better. But generally, repetitions of 1000 or more are not necessary. Around 100 to 200 simulations are usually sufficient. We saw in the previous section that the sample proportion Pˆ follows a binomial distribution, and so we can use a calculator to investigate repeated sampling.
Example 11 Assume that 55% of people in Australia have blue eyes. Use your calculator to illustrate a possible distribution of sample proportions pˆ that may be obtained when 200 di↵erent samples (each of size 100) are selected from the population.
Using the TI-Nspire ⌅ To generate the sample proportions: • Start from a Lists & Spreadsheet page.
• Name the list ‘propblue’ in Column A. • In the formula cell of Column A, enter the formula using Menu > Data > Random > Binomial and complete as:
= randbin(100, 0.55, 200)/100 Note: The syntax is: randbin(sample size, population proportion, number of samples)
To calculate as a proportion, divide by the sample size.
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368 Chapter 12: Sampling and sampling distributions ⌅ To display the distribution of sample
proportions: • Insert a Data & Statistics page (
ctrl
I
or
). • Click on ‘Click to add variable’ on the x-axis and select ‘propblue’. A dotplot is displayed. ctrl doc H
Note: You can recalculate the random
sample proportions by using ctrl R while in the Lists & Spreadsheet page. ⌅ To fit a normal curve to the distribution: • •
Menu Menu
> Plot Type > Histogram > Analyze > Show Normal PDF
Note: The normal curve is superimposed
on the plot, showing the mean and standard deviation of the sample proportion. (Normal distributions are discussed in Section 12D.)
Using the Casio ClassPad ⌅ To generate the sample proportions: • Open the Statistics application
.
• Tap the ‘Calculation’ cell at the bottom
of list1. • Type: randBin(100, 0.55, 200)/100 • Tap Set .
Note: The syntax is: randBin(sample size, population proportion, number of samples)
To calculate as a proportion, divide by the sample size. ⌅ To display the distribution of sample proportions: • Tap on the Set StatGraphs icon G, select the
type ‘Histogram’ and tap Set . • Tap on the graph icon y in the toolbar. • In the Set Interval window, enter the values shown below and tap OK .
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12C Investigating the distribution of the sample proportion using simulation 369 ⌅ The histogram of sample proportions is shown.
⌅ To obtain statistics from the distribution, select Calc > One–Variable. Tap OK .
Note: The mean of the sample proportions, x¯,
estimates the population proportion.
Example 12 In a certain country, the literacy rate for adults is known to be 68%. a Use your calculator to simulate 100 samples, each of size 25, drawn at random from this population. Construct a dotplot of the proportion of people in each sample who are literate. b Use your dotplot to estimate the probability that the proportion of people in a sample of size 25 who are literate is 80% or more. Solution a
b ⌅ In the dotplot on the left, there are 15 out of 100 samples where the sample 15 proportion is 0.8 or more. This gives Pr(Pˆ 0.8) ⇡ = 0.15. 100 ⌅ In the histogram on the right, there are 5 out of 100 samples where the sample 5 proportion is 0.8 or more. This gives Pr(Pˆ 0.8) ⇡ = 0.05. 100
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370 Chapter 12: Sampling and sampling distributions
I The effect of sample size on the distribution of the sample proportion
Using simulation, we have seen that the sample proportion Pˆ has a symmetric bell-shaped distribution. We can also use simulation to explore how the distribution of the sample proportion is a↵ected by the size of the sample chosen. Again, we suppose that 55% of people in Australia have blue eyes (p = 0.55). The following dotplots show the sample proportions pˆ obtained when 200 samples of size 20, then size 50 and then size 200 were chosen from this population. Note: It is important not to confuse the size of each sample with the number of samples used
for the simulation, which is quite arbitrary. We used 200 simulations because this is sufficient to illustrate the features of the sampling distribution.
n = 20
n = 50
n = 200
0.25 0.30 0.35 0.40 0.45 0.50 0.55 0.60 0.65 0.70 0.75 0.80 0.85 Each symbol represents up to 2 observations.
We can see from the dotplots that all three sampling distributions are symmetric and centred at 0.55, the value of the population proportion p. Furthermore, as the sample size increases, the values of the sample proportion pˆ are more tightly clustered around that value. For example, we can see that for the particular 200 simulations used to construct each dotplot, a sample proportion pˆ of 0.75 or more was observed: ⌅ a few times when the sample size was 20 ⌅ only once when the sample size was 50 ⌅ never when the sample size was 200.
When the sample size is larger, we are less likely to get a value of the sample proportion that is very di↵erent from the population proportion. These observations are confirmed in following table, which gives the mean and standard deviation for each of the three simulated sampling distributions shown in the dotplots.
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12C Investigating the distribution of the sample proportion using simulation 371
12C
Sample size
20
50
200
Population proportion p
0.55
0.55
0.55
Mean of the values of pˆ
0.5475
0.5489
0.5492
Standard deviation of the values of pˆ
0.1164
0.0704
0.0331
The sampling distribution of Pˆ is symmetric and centred at the value of the population proportion p. The variation in the sampling distribution decreases as the size of the sample increases. When the population proportion p is not known, the sample proportion pˆ can be used as an estimate of this parameter. The larger the sample used to calculate the sample proportion, the more confident we can be that this is a good estimate of the population proportion.
Section summary ⌅ We can use technology (calculators or computers) to repeat a random sampling process
many times. This is known as simulation. ⌅ Through simulation, we can see that the sampling distribution of Pˆ is symmetric and centred at the value of the population proportion p. ⌅ The variation in the sampling distribution decreases as the size of the sample increases. ⌅ When the population proportion p is not known, we can use the sample proportion pˆ as an estimate of this parameter. The larger the sample size, the more confident we can be that pˆ is a good estimate of the population proportion p.
Exercise 12C Example 10
1
Researchers believe that 70% of people prefer brewed co↵ee to instant co↵ee. The following dotplot shows the values of the sample proportions obtained when 100 random samples of size 50 were generated from this population.
0.50
0.55
0.60
0.65
0.70
0.75
0.80
Use the dotplot to estimate: a Pr(Pˆ 0.8) b Pr(Pˆ 0.5)
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372 Chapter 12: Sampling and sampling distributions 2
12C
It is known that 45% of fish in a certain lake are underweight. The following dotplot shows the sample proportions of underweight fish obtained when 100 samples of size 20 were drawn from the lake.
0.20 0.25 0.30 0.35 0.40 0.45 0.50 0.55 0.60 0.65 0.70 0.75
Use the dotplot to estimate: a Pr(Pˆ 0.7) b Pr(Pˆ 0.25) Example 11, 12
3
A politician believes that 55% of her electorate will vote for her in the next election. a Use your calculator to simulate 100 values of the sample proportion of people who will vote for this politician in a random sample of size 100. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(Pˆ 0.64) ii Pr(Pˆ 0.44)
4
A shooter claims that he hits the target with 80% of his shots. a Assuming that his claim is correct, use your calculator to simulate 50 values of the sample proportion of targets hit when the shooter takes 50 shots. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(Pˆ 0.9) ii Pr(Pˆ 0.7)
5
One in three workers spend at least three-quarters of their work time sitting. a Use your calculator to simulate 100 values of the sample proportion of workers who spend at least three-quarters of their work time sitting, when a sample of 40 workers is drawn from this population. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(Pˆ 0.45) ii Pr(Pˆ 0.25)
6
a Repeat the simulation carried out in part a of Question 5, but this time using a sample of 80 workers. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(Pˆ 0.45) ii Pr(Pˆ 0.25) d Compare your answers to part c with those from Question 5.
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12D Investigating the distribution of the sample mean using simulation 373
12D Investigating the distribution of the sample mean using simulation In Section 12A, we saw that while the population mean µ is constant for a given population, the sample mean x¯ is not constant, but varies from sample to sample. In this section we use simulation to investigate this variation in the sample mean.
I The sample mean as a random variable Consider the random variable IQ, which has a mean of 100 and a standard deviation of 15 in the population. In order to use technology to investigate this random variable, we use a distribution that you may not have met before, called the normal distribution. You will study this distribution in Year 12, but for now it is enough to know that many commonly occurring random variables – such as height, weight and IQ – follow this distribution.
Frequency
This histogram shows the IQ scores of 1000 people randomly drawn from the population. 160 140 120 100 80 60 40 20 0
50 60 70 80 90 100 110 120 130 140 150
You can see that the distribution is symmetric and bell-shaped, with its centre of symmetry at the population mean. The normal distribution is fully defined by its mean and standard deviation. If we know these values, then we can use technology to generate random samples.
Using the TI-Nspire To generate a random sample of size 10 from a normal population with mean 100 and standard deviation 15: ⌅ Start from a Lists & Spreadsheet page. ⌅ Name the list ‘iq’ in Column A. ⌅ In the formula cell of Column A, enter the formula using Menu > Data > Random > Normal and complete as:
= randnorm(100, 15, 10) Note: The syntax is: randnorm(mean, standard deviation, sample size)
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374 Chapter 12: Sampling and sampling distributions Using the Casio ClassPad To generate a random sample of size 10 from a normal population with mean 100 and standard deviation 15: ⌅ In M, press the ⌅ ⌅ ⌅ ⌅
button. Find and then select Catalog by first tapping H at the bottom of the left sidebar. Scroll across the alphabet to the letter R. Select randNorm( and type: 15, 100, 10) Tap I to view all the values. Keyboard
Notes: ⌅ The syntax is: randNorm(standard deviation, mean,
sample size) ⌅ Alternatively, the random sample can be generated in the Statistics application.
One random sample of 10 scores, obtained by simulation, is 105, 109, 104, 86, 118, 100, 81, 94, 70, 88 Recall that the sample mean is denoted by x¯ and that P x x¯ = n P where means ‘sum’ and n is the size of the sample.
Here the sample mean is 105 + 109 + 104 + 86 + 118 + 100 + 81 + 94 + 70 + 88 x¯ = = 95.5 10 A second sample, also obtained by simulation, is 114, 124, 128, 133, 95, 107, 117, 91, 115, 104 with sample mean 114 + 124 + 128 + 133 + 95 + 107 + 117 + 91 + 115 + 104 x¯ = = 112.8 10 Since x¯ varies according to the contents of the random samples, we can consider the sample ¯ means x¯ as being the values of a random variable, which we will denote by X. Since x¯ is a statistic which is calculated from a sample, the probability distribution of the random variable X¯ is again called a sampling distribution.
I The sampling distribution of the sample mean Generating random samples and then calculating the mean from the sample is quite a tedious process if we wish to investigate the sampling distribution of X¯ empirically. Luckily, we can also use technology to simulate values of the sample mean. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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12D Investigating the distribution of the sample mean using simulation 375
Using the TI-Nspire To generate the sample means for 10 random samples of size 25 from a normal population with mean 100 and standard deviation 15: ⌅ Start from a Lists & Spreadsheet page. ⌅ Name the list ‘iq’ in Column A. ⌅ In cell A1, enter the formula using Menu > Data > Random > Normal and complete as:
= mean(randnorm(100, 15, 25)) ⌅ Fill down to obtain the sample means for 10 random samples. For a large number of simulations, an alternative method is easier. To generate the sample means for 500 random samples of size 25, enter the following formula in the formula cell of Column A: = seq(mean(randnorm(100, 15, 25)), k, 1, 500) The dotplot on the right was created this way.
Using the Casio ClassPad To generate the sample means for 10 random samples of size 25 from a normal population with mean 100 and standard deviation 15: ⌅ Open the Spreadsheet application
.
⌅ Tap in cell A1. ⌅ Type: = mean(randNorm(15, 100, 25)) ⌅ Go to Edit > Fill > Fill Range. ⌅ Type A1:A10 for the range and tap
OK .
To sketch a histogram of these sample means: ⌅ Go to Edit > Select > Select Range. ⌅ Type A1:A10 for the range and tap
OK .
⌅ Select Graph and tap Histogram.
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376 Chapter 12: Sampling and sampling distributions Suppose that 10 random samples (each of size 25) are selected from a population with mean 100 and standard deviation 15. The values of x¯ obtained might look like those in the following dotplot. The values look to be centred around 100, ranging from 97.3 to 109.2. 96
98
100
102
104
106
108
110
To better investigate the distribution requires more sample means. The following dotplot summarises the values of x¯ observed for 100 samples (each of size 25).
92
94
96
98
100
102
104
106
Example 13 The IQ scores for a population have mean 100 and standard deviation 15. Use the previous dotplot to estimate the probability that, for a random sample of 25 people drawn from this population, the sample mean x¯ is 104 or more. Solution From the dotplot we can count 6 out of 100 samples where the sample mean is 104 or more. Thus we can estimate 6 Pr(X¯ 104) ⇡ = 0.06 100
Example 14 Suppose it is known that parking times in a large city car park are normally distributed, with mean µ = 223 minutes and standard deviation = 48 minutes. a Use your calculator to generate the sample means for 100 samples, each of size 25, drawn at random from this population. Summarise these values in a dotplot. b Use your dotplot to estimate the probability that, in a random sample of 25 cars, the mean parking time is greater than or equal to 240 minutes. Solution a
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12D Investigating the distribution of the sample mean using simulation 377
b ⌅ In the dotplot on the left, there are 3 out of 100 samples where the sample mean 3 is 240 or more. This gives Pr(X¯ 240) ⇡ = 0.03. 100 ⌅ In the histogram on the right, there are 2 out of 100 samples where the sample mean 2 is 240 or more. This gives Pr(X¯ 240) ⇡ = 0.02. 100 This histogram shows the sampling distribution of the sample mean when 1000 samples (each of size 25) were selected from a population with mean 100 and standard deviation 15. 140
Frequency
120 100 80 60 40 20 0
92 94 96 98 100 102 104 106 108 110
We can see from this plot that the distribution of sample means is symmetric and bell-shaped, suggesting that the sampling distribution of the sample mean may also be described by the normal distribution. This is an area of study which will be further explored in Year 12. How does the sampling distribution of the values of X¯ (where each value is the mean of a sample of size 25) compare to the distribution of the individual values of X? The following plot shows the two previous histograms together with the same scale. 500
Frequency
400 300
Individual value of IQ Mean IQ of sample of size 25
200 100 0
60
80 100 120 140
We can see that while both distributions are symmetric and bell-shaped, and centred at the value of the population mean, they exhibit very di↵erent variation. The individual IQ scores are clustered between 70 and 130, but the sample means are almost all between 90 and 110. On reflection, this seems quite reasonable. While it would not be very unusual to find an individual person in the population with an IQ over 130, for example, it would seem highly unlikely that we would select a random sample of 25 people from the population and find that their mean IQ was over 130. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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378 Chapter 12: Sampling and sampling distributions
I The effect of sample size on the distribution of the sample mean Using simulation, we have seen that the sample mean X¯ has a symmetric bell-shaped distribution. We can also use simulation to explore how the distribution of the sample mean is a↵ected by the size of the sample chosen. The following dotplots show the sample means x¯ obtained when 200 samples of size 25, then size 100 and then size 200 were chosen from a population. Again, it is important not to confuse the size of each sample with the number of samples used for the simulation, which is quite arbitrary.
n = 25
n = 100
n = 200
92 94 96 98 100 102 Each symbol represents up to 2 observations
104
106
108
110
We can see from the dotplots that all three sampling distributions appear to be centred at 100, the value of the population mean µ. Furthermore, as the sample size increases, the values of the sample mean x¯ are more tightly clustered around that value. These observations are confirmed in following table, which gives the mean and standard deviation for each of the three simulated sampling distributions shown in the dotplots. Sample size
25
100
200
Population mean µ
100
100
100
Mean of the values of x¯
99.24
100.24
100.03
Standard deviation of the values of x¯
3.05
1.59
1.06
The sampling distribution of X¯ is symmetric and centred at the value of the population mean µ. The variation in the sampling distribution decreases as the size of the sample increases. When the population mean µ is not known, the sample mean x¯ can be used as an estimate of this parameter. The larger the sample used to calculate the sample mean, the more confident we can be that this is a good estimate of the population mean.
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12D Investigating the distribution of the sample mean using simulation 379
12D
Section summary ⌅ The sample mean X¯ is a random variable and so can be described by a probability
distribution, called the sampling distribution of the sample mean. ⌅ Through simulation, we can see that the sampling distribution of X¯ is symmetric and centred at the value of the population mean µ. ⌅ The variation in the sampling distribution decreases as the size of the sample increases. ⌅ When the population mean µ is not known, the sample mean x¯ can be used as an estimate of this parameter. The larger the sample size, the more confident we can be that x¯ is a good estimate of the population mean µ.
Exercise 12D Example 13
1
In a certain city, the average size of a kindergarten class is µ = 24 children, with a standard deviation of = 2. The following dotplot shows the sample means x¯ for 100 random samples of 20 classes.
22.5
23.0
23.5
24.0
24.5
25.0
25.5
Use the dotplot to estimate: a Pr(X¯ 25) b Pr(X¯ 23) 2
The mean height of women in a certain country is µ = 160 cm, with a standard deviation of = 8 cm. The following dotplot shows the sample means x¯ for 100 random samples of 30 women.
156
157
158
159
160
161
162
163
164
Use the dotplot to estimate: a Pr(X¯ 163) b Pr(X¯ 158) Example 14
3
The lengths of a species of fish are normally distributed with mean length µ = 40 cm and standard deviation = 4 cm. a Use your calculator to simulate 100 values of the sample mean calculated from a sample of size 50 drawn from this population of fish. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(X¯ 41) ii Pr(X¯ 39)
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380 Chapter 12: Sampling and sampling distributions 4
12D
The marks in a statistics examination in a certain university are normally distributed with a mean of µ = 48 marks and a standard deviation of = 15 marks. a Use your calculator to simulate 100 values of the sample mean calculated from a sample of size 20 drawn from the students at this university. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(X¯ 55) ii Pr(X¯ 40)
5
At the Fizzy Drinks Company, the volume of soft drink in a 1 litre bottle is normally distributed with mean µ = 1 litre and standard deviation = 0.01 litres. a Use your calculator to simulate 100 values of the sample mean calculated from a sample of 25 bottles from this company. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(X¯ 1.003) ii Pr(X¯ 0.995)
6
a Repeat the simulation carried out in part a of Question 5, but this time using samples of 50 bottles. b Summarise the values obtained in part a in a dotplot. c Use your dotplot to estimate: i Pr(X¯ 1.003) ii Pr(X¯ 0.995) d Compare your answers in part c to those from Question 5.
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Chapter 12 review 381
⌅ A population is the set of all eligible members of a group which we intend to study. AS
⌅ A sample is a subset of the population which we select in order to make inferences about
Nrich
⌅ ⌅
⌅ ⌅ ⌅ ⌅ ⌅ ⌅
the population. Generalising from the sample to the population will not be useful unless the sample is representative of the population. The simplest way to obtain a valid sample is to choose a random sample, where every member of the population has an equal chance of being included in the sample. The population proportion p is the proportion of individuals in the entire population possessing a particular attribute; the sample proportion pˆ is the proportion of individuals in a particular sample possessing this attribute. The population mean µ is the mean of all values of a measure in the entire population; the sample mean x¯ is the mean of these values in a particular sample. Both the population proportion p and the population mean µ are population parameters; their values are constant for a given population. Both the sample proportion pˆ and the sample mean x¯ are sample statistics; their values are not constant, but vary from sample to sample. For a discrete random variable X, the probability distribution of X is a function p(x) = Pr(X = x) that assigns a probability to each value of X. Both the sample proportion Pˆ and the sample mean X¯ can be viewed as random variables, and their distributions are called sampling distributions. When the population is small, the sampling distribution of the sample proportion Pˆ can be determined using the hypergeometric distribution: The probability of obtaining x defectives in a sample of size n is given by ! ! D N D x n x ! Pr(X = x) = for x = 0, 1, 2, . . . , min(n, D) N n
Review
Chapter summary
where N is the size of the population and D is the number of defectives in the population. ⌅ When the population is large, the sampling distribution of the sample proportion Pˆ can be determined using the binomial distribution: The probability of achieving x successes in a sequence of n trials is given by ! n x Pr(X = x) = p (1 p)n x for x = 0, 1, 2, . . . , n x
where p is the probability of success on each trial. ⌅ We can use technology (calculators or computers) to repeat a random sampling process many times. This is known as simulation. ⌅ Through simulation, we see that the sampling distribution of the sample proportion Pˆ is symmetric and centred at the value of the population proportion p, and that the sampling distribution of the sample mean X¯ is symmetric and centred at the value of the population mean µ. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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Review
382 Chapter 12: Sampling and sampling distributions ⌅ The variation in the sampling distribution decreases as the size of the sample increases. ⌅ When a population parameter (such as p or µ) is not known, we can use the associated
sample statistic (such as pˆ or x¯) as an estimate of this parameter. The larger the sample size, the more confident we can be that the sample statistic gives a good estimate of the population parameter.
Technology-free questions 1
A company has 2000 employees, 700 of whom are female. A random sample of 100 employees was selected, and 40 of them were female. In this example: a What is the population? b What is the value of the population proportion p? c What is the value of the sample proportion p? ˆ
2
To study the e↵ectiveness of yoga for reducing stress, a researcher measured the stress levels of 50 people who had just enrolled in a 10-week introductory yoga course, and then measured their stress at the end the course. Do you think that this sample will be representative of the general population? Explain your answer.
3
Social researchers suggested that people who spend more time gardening also tend to spend more time on housework. They randomly selected 120 people who lived in houses with a garden and over the course of one month, measured the amount of time they spent gardening and the amount of time they spent on housework. Do you think this sample will be representative of the general population? Explain your answer.
4
Medical researchers were interested in the amount of water consumed by people with Type II diabetes, which they suspect may be more than the 1 litre per day average observed in the general population. They randomly selected a sample of 50 people with Type II diabetes and found their average daily water consumption was 1.5 litres per day. a b c d
5
What is the population of interest here? Why did the researchers select a sample rather than studying the entire population? What is the value of the population mean µ? What is the value of the sample mean x¯?
A company has 5400 employees, 1080 of whom have a tertiary qualification. A group of 200 employees were selected to complete a survey, and 44 of them were tertiary qualified. In this example: a What is the population? b What is the value of the population proportion p? c What is the value of the sample proportion pˆ ?
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Chapter 12 review 383
A tennis team has five members: two males and three females. a What is p, the proportion of females in the tennis team? b Three players are to be selected at random to play in a tournament. What are the possible values of the sample proportion pˆ of females in the selected group? c Use the hypergeometric distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of females when samples of size 3 are selected from the tennis team. d Use the sampling distribution from c to determine the probability that the proportion of females in the selected group is more than 0.5. e Find Pr(0 < Pˆ < 0.5) and hence find Pr(Pˆ < 0.5 | Pˆ > 0).
7
Review
6
Suppose that the probability of a male child being born is 0.5. Of the next four children born at a maternity hospital: a What are the possible values of the sample proportion pˆ of male children born? b Use the binomial distribution to construct a probability distribution table which summarises the sampling distribution of the sample proportion of male children born. c Use the sampling distribution from b to determine the probability that the proportion of male children born is less than 0.5. d Find Pr(Pˆ < 0.5 | Pˆ < 0.8).
8
It is known that 55% of people in a certain electorate voted for Bill Bloggs in the last election. The following dotplot shows the distribution of sample proportions obtained when 100 samples of size 50 were drawn from a population with population proportion 0.55.
0.34 0.38 0.42 0.46 0.50 0.54 0.58 0.62 0.66 0.70 0.74
a Use the dotplot to estimate: i Pr(Pˆ 0.70) ii Pr(Pˆ 0.38)
b One of Bill Bloggs’s team members selects a random sample of 50 people from the electorate and finds that only 21 intend to vote for Bill Bloggs at the next election. i What is the value of the sample proportion p? ˆ ii Use the dotplot to determine how likely it is that, if the proportion of people supporting Bill Bloggs is still 55%, we would find a value of pˆ as low as or lower than this value.
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Review
384 Chapter 12: Sampling and sampling distributions
Multiple-choice questions 1
In order to estimate the ratio of males to females at a school, a teacher determines the number of males and the number of females in a particular class. The ratio that he then calculates is called a A sample D population
2
B sample statistic E sample parameter
In a complete census of the population of a particular community, it is found that 59% of families have two or more children. Here ‘59%’ represents the value of a A sample D population
3
C population parameter
We use sample statistics to estimate population parameters. We use sample parameters to estimate population statistics. We use population parameters to estimate sample statistics. We use population statistics to estimate sample parameters. None of the above.
A sampling distribution can best be described as a distribution which A B C D E
5
B sample statistic E sample parameter
Which of the following statements is true? A B C D E
4
C population parameter
gives the most likely value of the sample statistic describes how a statistic’s value will change from sample to sample describes how samples do not give reliable estimates gives the distribution of the values observed in a particular sample None of the above.
Which of the following statements is generally correct? A B C D E
µ is an estimate of x¯, and pˆ is an estimate of x¯ is an estimate of µ, and pˆ is an estimate of µ is an estimate of p, ˆ and x¯ is an estimate of x¯ is an estimate of µ, and p is an estimate of µ is an estimate of x¯, and p is an estimate of
6
pˆ Pr(Pˆ = p) ˆ
0
0.2
0.4
0.6
0.8
1
0.116
0.312
0.336
0.181
0.048
0.005
Using this table, the value of Pr(Pˆ A 0.053
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p p p pˆ pˆ
B 0.143
0.7 | Pˆ > 0.2) is
C 0.060
D 0.572
E 0.093
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Chapter 12 review 385
Noah has invited 10 friends to a dinner party, and four of them are vegetarians. He has only six china plates, and so four guests will have to use plastic plates. If the plastic plates are distributed among the guests at random, then the probability that the proportion of vegetarians using plastic plates is more than 0.5 is closest to A 0.119
8
B 0.114
B 0.2592
B 0.0115
D 0.3065
E 0.3370
C 0.0054
D 0.1369
E 0.0691
B about 2% E none of these
C about 5%
When is it appropriate to use the binomial distribution to calculate the probabilities related to the sampling distribution of the sample proportion? A B C D E
12
C 0.0778
If a fair coin is tossed 10 times, then the probability that the proportion of heads obtained is less than 20% or more than 80% is A close to zero D about 10%
11
E 0.881
It is known that 20% of students in a very large school study Chinese. The probability that, in a random sample of 20 students, the proportion of students who study Chinese is less than 10% is closest to A 0.0160
10
D 0.179
Ethan puts 20 fish in his new fishpond: 12 gold and 8 black. If he catches a random sample of five fish the next day to check their health, what is the probability that 80% or more of the sample are gold fish? A 0.0063
9
C 0.154
Review
7
when the population is small and the sample size is small whenever the sample size is small when the sample size is small compared to the population size when the sample size is large and the population size is small never appropriate
A market research company has decided to increase the size of the random sample of Australians that it will select for a survey, from about 1000 people to about 1500 people. What is the e↵ect of this increase in sample size? A B C D E
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The increase will ensure that the sampling distribution is symmetric. The e↵ect cannot be predicted without knowing the population size. There will be no e↵ect as the population size is the same. The variability of the sample estimate will increase, as more people are involved. The variability of the sample estimate will decrease.
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Review
386 Chapter 12: Sampling and sampling distributions
Extended-response questions 1
a Use simulation to generate sampling distributions for the sample proportion obtained when samples of size 50 are drawn from populations with values of the population proportion p = 0.1, 0.2, 0.3, 0.4, 0.5, 0.6. (Generate 100 samples for each value of p.) Construct dotplots of the sampling distributions and, by counting five values in from each end, use them to find the lower limit a and upper limit b such that Pr(a Pˆ b) ⇡ 0.90.
p
a
b
0.1 0.2 0.3 0.4 0.5 0.6
b Miller wishes to estimate the proportion of people in a certain city who are left-handed. He selects a random sample of 50 people, and finds that 17 are left-handed. i What is the value of the sample proportion here? ii Refer to the table you constructed in part a. If a possible value of the population proportion is one where the observed value of the sample proportion lies within the interval [a, b] such that Pr(a Pˆ b) ⇡ 0.90, which values of p are consistent with Miller’s sample? 2
For a certain type of mobile phone, the length of time between charges of the battery is normally distributed with a mean of 50 hours and a standard deviation of 5 hours. a
i Use your calculator to simulate 100 values of the sample mean calculated from a sample of 20 phones. ii Summarise the values obtained in part i in a dotplot. iii Determine the mean and standard deviation of this sampling distribution. b i Use your calculator to simulate 100 values of the sample mean calculated from a sample of 50 phones. ii Summarise the values obtained in part i in a dotplot. iii Determine the mean and standard deviation of this sampling distribution. c i Use your calculator to simulate 100 values of the sample mean calculated from a sample of 100 phones. ii Summarise the values obtained in part i in a dotplot. iii Determine the mean and standard deviation of this sampling distribution. d It can be shown theoretically that the standard deviation of the sampling distribution p is inversely proportional to n, where n is the sample size. Use your answers to parts a–c to demonstrate this relationship empirically.
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Chapter 13
13
Trigonometric ratios and applications
Objectives I I I I I I I I
To solve practical problems using the trigonometric ratios. To use the sine rule and the cosine rule to solve problems. To find the area of a triangle given two sides and the included angle. To find the length of an arc and the length of a chord of a circle. To find the area of a sector and the area of a segment of a circle. To solve problems involving angles of elevation and angles of depression. To identify the line of greatest slope of a plane. To solve problems in three dimensions, including determining the angle between planes.
Trigonometry deals with the side lengths and angles of a triangle: the word trigonometry comes from the Greek words for triangle and measurement. In Chapter 9, we used the four standard congruence tests for triangles. If you have the information about a triangle given in one of the congruence tests, then the triangle is uniquely determined (up to congruence). You can find the unknown side lengths and angles of the triangle using the sine rule or the cosine rule. In this chapter, we will apply these rules in two- and three-dimensional problems. In Chapter 10, we studied the geometry of the circle, and the results involved chords, secants and arcs. In this chapter, we use trigonometry to determine the associated lengths and angles. We also find the areas of sectors and segments of circles. Note: An introduction to sine, cosine and tangent as functions is given in Mathematical
Methods Units 1 & 2 and also in an online chapter for this book, available in the Interactive Textbook.
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388 Chapter 13: Trigonometric ratios and applications
13A Reviewing trigonometry In this section we review sine, cosine and tangent for angles between 0 and 180 .
I Defining sine and cosine
y
The unit circle is a circle of radius 1 with centre at the origin.
(0, 1)
We can define the sine and cosine of any angle by using the unit circle. (–1, 0)
x
(0, 0) (1, 0) (0, –1)
Unit-circle definition of sine and cosine
y
For each angle ✓ , there is a point P on the unit circle as shown. The angle is measured anticlockwise from the positive direction of the x-axis.
P(cos(θ°), sin(θ°)) θ° (0, 0)
⌅ cos(✓ ) is defined as the x-coordinate of the point P
x
⌅ sin(✓ ) is defined as the y-coordinate of the point P
I The trigonometric ratios For acute angles, the unit-circle definition of sine and cosine given above is equivalent to the ratio definition. For a right-angled triangle OBC, we can construct a similar triangle OB0C 0 that lies in the unit circle. From the diagram: B0C 0 = sin(✓ )
B
and OC 0 = cos(✓ )
B¢
The similarity factor is the length OB, giving BC = OB sin(✓ ) )
BC = sin(✓ ) OB
and
OC = OB cos(✓ )
and
OC = cos(✓ ) OB
1 O
θ°
C
C¢
This gives the ratio definition of sine and cosine for a right-angled triangle. The naming of sides with respect to an angle ✓ is as shown. opposite sin(✓ ) = hypotenuse adjacent cos(✓ ) = hypotenuse opposite tan(✓ ) = adjacent Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
B hypotenuse
O
opposite
θ° adjacent C
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13A Reviewing trigonometry 389
I Obtuse angles From the unit circle, we see that sin(180
✓) = sin(✓ )
cos(180
✓) =
cos(✓ )
y (cos(180 – q)°, sin(180 – q)°)
(180 – q)°
For example: sin 135 = sin 45 cos 135 =
q°
0
(cos(q°), sin(q°)) x
cos 45
In this chapter, we will generally use the ratio definition of tangent for acute angles. But we can also find the tangent of an obtuse angle by defining tan ✓ =
sin ✓ cos ✓
We will not consider angles greater than 180 or less than 0 in this chapter, since we are dealing with triangles.
I Solving right-angled triangles Here we provide some examples of using the trigonometric ratios.
Example 1 a Find the value of x correct to two decimal places.
b Find the length of the hypotenuse correct to two decimal places. B
C 80 cm A
x cm
29.6°
B
Solution x a = sin 29.6 80
A
b
) x = 80 sin 29.6 = 39.5153 . . . Hence x = 39.52, correct to two decimal places.
15° 10 cm
C
10 = cos 15 AB 10 = AB cos 15 10 ) AB = cos 15 = 10.3527 . . . The length of the hypotenuse is 10.35 cm, correct to two decimal places.
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390 Chapter 13: Trigonometric ratios and applications
13A
Example 2 A
Find the magnitude of \ABC.
11 cm B
Solution tan x = )
11 3
x = tan
1
x° 3 cm
C
✓ 11 ◆
3 = (74.7448 . . . )
Hence x = 74.74 , correct to two decimal places.
Exercise 13A Example 1, 2
1
Find the value of x in each of the following: a
b 5 cm
35°
10 cm
x cm
5°
x cm
c
d x cm
x cm
20.16° 8 cm
30.25° 7 cm
e
f 10 cm x°
15 cm
10 cm 40°
x cm
2
An equilateral triangle has altitudes of length 20 cm. Find the length of one side.
3
The base of an isosceles triangle is 12 cm long and the equal sides are 15 cm long. Find the magnitude of each of the three angles of the triangle.
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13A Reviewing trigonometry 391
13A 4
A pole casts a shadow 20 m long when the altitude of the sun is 49 . Calculate the height of the pole.
pole 49° 20 m
5
This figure represents a ramp. a Find the magnitude of angle ACB. b Find the distance BC.
6
A 6m C
B
This figure shows a vertical mast PQ, which stands on horizontal ground. A straight wire 20 m long runs from P at the top of the mast to a point R on the ground, which is 10 m from the foot of the mast. a Calculate the angle of inclination, ✓ , of the wire to the ground. b Calculate the height of the mast.
7
1m
P
20 m
θ° R
Q
10 m
A ladder leaning against a vertical wall makes an angle of 26 with the wall. If the foot of the ladder is 3 m from the wall, calculate: a the length of the ladder b the height it reaches above the ground.
8
An engineer is designing a straight concrete entry ramp, 60 m long, for a car park that is 13 m above street level. Calculate the angle of the ramp to the horizontal.
9
A vertical mast is secured from its top by straight cables 200 m long fixed at the ground. The cables make angles of 66 with the ground. What is the height of the mast?
10
A mountain railway rises 400 m at a uniform slope of 16 with the horizontal. What is the distance travelled by a train for this rise?
11
The diagonals of a rhombus bisect each other at right angles. If BD = AC = 10 cm, find:
B
C
a the length of the sides of the rhombus b the magnitude of angle ABC.
A Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
D
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392 Chapter 13: Trigonometric ratios and applications 12
13A
A pendulum swings from the vertical through an angle of 15 on each side of the vertical. If the pendulum is 90 cm long, what is the distance, x cm, between its highest and lowest points?
90 cm
90 cm
x cm
13
14
A picture is hung symmetrically by means of a string passing over a nail, with the ends of the string attached to two rings on the upper edge of the picture. The distance between the rings is 30 cm, and the string makes an angle of 105 at the nail. Find the length of the string.
105 ° 30 cm
The distance AB is 50 m. If the line of sight to the tree of a person standing at A makes an angle of 32 with the bank, how wide is the river? 32° 50 m
B
A
15
A ladder 4.7 m long is placed against a wall. The foot of the ladder must not be placed in a flower bed, which extends a distance of 1.7 m out from the base of the wall. How high up the wall can the ladder reach?
16
A river is known to be 50 m wide. A swimmer sets o↵ from A to cross the river, and the path of the swimmer AB is as shown. How far does the person swim?
B
50 m 60° A
17
A rope is tied to the top of a flagpole. When it hangs straight down, it is 2 m longer than the pole. When the rope is pulled tight with the lower end on the ground, it makes an angle of 60 to the horizontal. How tall is the flagpole?
18
The triangle shown has perimeter 10. Find the value of x. 30° x
19
Consider the circle with equation x2 + y2 4y = 0 and the point P(5, 2). Draw a diagram to show the circle and the two lines from P that are tangent to the circle. Find the angle between the two tangent lines, \APB, where A and B are the two points of contact.
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13B The sine rule 393
13B The sine rule In the previous section, we focused on right-angled triangles. In this section and the next, we consider non-right-angled triangles. The sine rule is used to find unknown side lengths or angles of a triangle in the following two situations: 1 one side and two angles are given 2 two sides and a non-included angle are given (that is, the given angle is not ‘between’ the two given sides). In the first case, the triangle is uniquely defined up to congruence. In the second case, there may be two triangles.
Labelling triangles The following convention is used in the remainder of this chapter: ⌅ Interior angles are denoted by uppercase letters.
B
c
⌅ The length of the side opposite an angle is denoted by the
A
corresponding lowercase letter.
a C
b
For example, the magnitude of angle BAC is denoted by A, and the length of side BC is denoted by a. Sine rule
For triangle ABC:
B
c
a b c = = sin A sin B sin C
A
a C
b
Proof We will give a proof for acute-angled triangles. The proof for obtuse-angled triangles is similar. In triangle ACD:
C
h sin A = b )
h sin B = a
i.e.
h
a
h = b sin A
In triangle BCD:
)
b
A
D
B
a sin B = b sin A a b = sin A sin B
Similarly, starting with a perpendicular from A to BC would give b c = sin B sin C
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394 Chapter 13: Trigonometric ratios and applications
I One side and two angles When one side and two angles are given, this corresponds to the AAS congruence test. The triangle is uniquely defined up to congruence.
Example 3 Use the sine rule to find the length of AB.
B c A
70° 31° 10 cm
C
Solution c 10 = sin 31 sin 70 )
c=
10 sin 31 sin 70
= 5.4809 . . . The length of AB is 5.48 cm, correct to two decimal places.
I Two sides and a non-included angle Suppose that we are given the two side lengths 7 m and 9 m and a non-included angle of 45 . There are two triangles that satisfy these conditions, as shown in the diagram. A 9m
7m 7m
45° B
C
C¢
Warning ⌅ When you are given two sides and a non-included angle, you must consider the
possibility that there are two such triangles. ⌅ An angle found using the sine rule is possible if the sum of the given angle and the found angle is less than 180 . Note: If the given angle is obtuse or a right angle, then there is only one such triangle.
The following example illustrates the case where there are two possible triangles.
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13B The sine rule 395
13B Example 4 Use the sine rule to find the magnitude of angle XZY in the triangle, given that Y = 25 , y = 5 cm and z = 6 cm. Solution
25°
X
6 cm
Y
Z1
5 6 = sin 25 sin Z
30.47° 149.53°
sin Z sin 25 = 6 5
5 cm
Z2
5 cm
6 sin 25 sin Z = 5 = 0.5071 . . .
25°
X
Z = (30.473 . . . )
)
Z
5 cm
or
Z = (180
6 cm
Y
30.473 . . . )
Hence Z = 30.47 or Z = 149.53 , correct to two decimal places. Note: Remember that sin(180
✓) = sin(✓ ).
Section summary ⌅ Sine rule For triangle ABC:
c
a b c = = sin A sin B sin C
A
B
a b
C
⌅ When to use the sine rule: • one side and two angles are given (AAS)
• two sides and a non-included angle are given.
Exercise 13B Skillsheet Example 3
1
Find the value of the pronumeral for each of the following triangles: a
b
Y 70°
X
Z x cm Y
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
28°
5.6 cm 100°
y cm
Z
10 cm
c
65°
x cm
50°
X
Z
37°
X
d
Y
6 cm 12 cm 38° x cm
Y X
90° Z
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396 Chapter 13: Trigonometric ratios and applications Example 4
2
13B
Find the value of ✓ for each of the following triangles: a
b
C
A θ°
72° 7 cm
A
c
9.4 cm 8 cm
θ°
42° B
8.3 cm
C
d
C
B
10 cm
8 cm
8 cm A
3
108°
θ°
B
A
θ°
38° 9 cm
C
Solve the following triangles (i.e. find all sides and angles): a a = 12, B = 59 , C = 73 c A = 123.2 , a = 11.5, C = 37 e B = 140 , b = 20, A = 10
4
B
b A = 75.3 , b = 5.6, B = 48.25 d A = 23 , a = 15, B = 40
Solve the following triangles (i.e. find all sides and angles): a b = 17.6, C = 48.25 , c = 15.3 c A = 28.35 , a = 8.5, b = 14.8
b B = 129 , b = 7.89, c = 4.56
5
A landmark A is observed from two points B and C, which are 400 m apart. The magnitude of angle ABC is measured as 68 and the magnitude of angle ACB as 70 . Find the distance of A from C.
6
P is a point at the top of a lighthouse. Measurements of the length AB and angles PBO and PAO are as shown in the diagram. Find the height of the lighthouse.
P
A
27.6° 46.2° 34 m B
O
7
A and B are two points on a coastline, and C is a point at sea. The points A and B are 1070 m apart. The angles CAB and CBA have magnitudes of 74 and 69 respectively. Find the distance of C from A.
8
Find:
Y
a AX b AY
X
88° A
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32°
20° 50 m
89° B
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13C The cosine rule 397
13B 9
Use the sine rule to establish the following identities for triangles: a b sin A sin B a + b sin A + sin B a = b = c sin C c sin C
13C The cosine rule The cosine rule is used to find unknown side lengths or angles of a triangle in the following two situations: 1 two sides and the included angle are given 2 three sides are given. In each case, the triangle is uniquely defined up to congruence. Cosine rule
For triangle ABC: 2
2
a =b +c
2
B
c
2bc cos A
A
b
or equivalently cos A =
a C
b2 + c2 a2 2bc
Proof We will give a proof for acute-angled triangles. The proof for obtuse-angled triangles is similar. In triangle ACD: x cos A = b
C
b
x = b cos A
)
Using Pythagoras’ theorem in triangles ACD and BCD: 2
2
b = x +h a2 = (c
A
a h x
2
D
c
B
x)2 + h2
Expanding gives a2 = c2 = c2 )
2cx + x2 + h2 2cx + b2
a2 = b2 + c2
2bc cos A
(as b2 = x2 + h2 ) (as x = b cos A)
I Two sides and the included angle When two sides and the included angle are given, this corresponds to the SAS congruence test. The triangle is uniquely defined up to congruence.
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398 Chapter 13: Trigonometric ratios and applications Example 5 B
For triangle ABC, find the length of AB in centimetres correct to two decimal places.
5 cm
c
67° 10 cm
A
C
Solution c2 = 52 + 102
2 ⇥ 5 ⇥ 10 cos 67
= 85.9268 . . . )
c = 9.2696 . . .
The length of AB is 9.27 cm, correct to two decimal places.
I Three sides When three sides are given, this corresponds to the SSS congruence test. The triangle is uniquely defined up to congruence.
Example 6 B
Find the magnitude of angle ABC.
12 cm
6 cm A
Solution cos B = =
C
15 cm
a2 + c2 b2 2ac 122 + 62 152 2 ⇥ 12 ⇥ 6
= 0.3125 )
B = (108.2099 . . . )
The magnitude of angle ABC is 108.21 , correct to two decimal places.
Section summary ⌅ Cosine rule For triangle ABC:
a2 = b2 + c2
2bc cos A
or
cos A =
b2 + c2 a2 2bc
⌅ When to use the cosine rule: • two sides and the included angle are given (SAS) • three sides are given (SSS).
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
c A
B
a b
C
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13C The cosine rule 399
13C
Exercise 13C Skillsheet
1
Find the length of BC.
B 10 cm 15° A 15 cm
Example 5
Example 6
2
Find the magnitudes of angles ABC and ACB.
C
B 8 cm A
3
4
C
10 cm
For triangle ABC with: a A = 60
b = 16
c = 30,
find a
b a = 14
B = 53
c = 12,
find b
c a = 27
b = 35
c = 46,
find the magnitude of angle ABC
d a = 17
B = 120
c = 63,
find b
e a = 31
b = 42
C = 140 ,
find c
f a = 10
b = 12
c = 9,
find the magnitude of angle BCA
g a = 11
b=9
C = 43.2 ,
find c
h a=8
b = 10
c = 15,
find the magnitude of angle CBA. B
A section of an orienteering course is as shown. Find the length of leg AB. A
5
5 cm
Two ships sail in di↵erent directions from a point O. At a particular time, their positions A and B are as shown. Find the distance between the ships at this time.
4 km 20° 6 km
C
N A B 6 km 30°
4 km
O
6
A weight is hung from two hooks in a ceiling by strings of length 54 cm and 42 cm, which are inclined at 70 to each other. Find the distance between the hooks.
42 cm
54 cm 70°
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400 Chapter 13: Trigonometric ratios and applications 7
13C
ABCD is a parallelogram. Find the lengths of the diagonals:
C
4 cm
a AC b BD
A
8
5 cm
B
48°
D
a Find the length of diagonal BD. b Use the sine rule to find the length of CD.
B
A 92°
4 cm 5 cm 88° C 6 cm
D
9
Two circles of radius 7.5 cm and 6 cm have a common chord of length 8 cm.
A 7.5 cm
0
a Find the magnitude of angle AO B. b Find the magnitude of angle AOB. 10
8 cm
O
6 cm O¢
B
Two straight roads intersect at an angle of 65 . A point A on one road is 90 m from the intersection and a point B on the other road is 70 m from the intersection, as shown.
A 90 m
a Find the distance of A from B. b If C is the midpoint of AB, find the distance of C from the intersection.
C
65°
O
70 m
B
13D The area of a triangle The area of a triangle is given by 1 Area = ⇥ base length ⇥ height 2 1 = bh 2
B c A
a
h
C
b
By observing that h = c sin A, we obtain the following formula. For triangle ABC: 1 Area = bc sin A 2
c A
B
a b
C
That is, the area is half the product of the lengths of two sides and the sine of the angle included between them. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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13D The area of a triangle 401
Example 7 B
Find the area of triangle ABC shown in the diagram.
7.2 cm
140°
6.5 cm
A
Solution Area =
C
1 ⇥ 7.2 ⇥ 6.5 sin 140 2
= 15.04 cm2
(correct to two decimal places)
Example 8 Find the area of each of the following triangles, correct to three decimal places: a
b D
A 8 cm
85°
10 cm
B
8.2 cm
70°
F
E
c G 10 cm
7 cm I
12°
6.4 cm
H
C
Solution a Using the cosine rule: 82 = 6.42 + 102 64 = 140.96
2 ⇥ 6.4 ⇥ 10 cos C
128 cos C
cos C = 0.60125 ) C = (53.0405 . . . ) 1 ⇥ 6.4 ⇥ 10 ⇥ sin C 2 = 25.570 cm2
Area 4ABC =
b Note that E = (180 Using the sine rule:
(store exact value on your calculator)
(correct to three decimal places)
(70 + 85)) = 25 .
8.2 sin 85 = 3.4787 . . .
(store exact value on your calculator)
1 ⇥ 8.2 ⇥ DF ⇥ sin 70 2 = 13.403 cm2
(correct to three decimal places)
DF = sin 25 ⇥
Area 4DEF =
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402 Chapter 13: Trigonometric ratios and applications
13D
c Using the sine rule: sin 12 7 = 0.2970 . . .
sin I = 10 ⇥ )
I = (180
17.27 . . . )
= (162.72 . . . ) ) G = (180
(since I is an obtuse angle) (store exact value on your calculator)
(12 + I))
= (5.27 . . . )
(store exact value on your calculator)
1 ⇥ 10 ⇥ 7 ⇥ sin G 2 = 3.220 cm2
(correct to three decimal places)
Area 4GHI =
Section summary For triangle ABC:
c
1 Area = bc sin A 2
B
A
a C
b
That is, the area is half the product of the lengths of two sides and the sine of the angle included between them.
Exercise 13D Skillsheet Example 7
1
Find the area of each of the following triangles: a
b
C 70°
6 cm
X 72.8° 6.2 cm
4 cm
5.1 cm Z
A
B Y
c
M
3.5 cm
130°
N
d
B
8.2 cm
25° 5 cm C
L
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A
5 cm
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13E Circle mensuration 403
13D Example 8
2
Find the area of each of the following triangles, correct to three decimal places: a A
b A 9 cm
5.9 cm C
4.1 cm
C
7 cm 100°
3.2 cm
B
B
c
d
E
E 5.7 cm
6.3 cm D
D 65°
5.9 cm
5.1 cm 55° F
F
e G
f G
12 cm 24°
5 cm
H
10° 4 cm
H
19° I
I
13E Circle mensuration I Terminology
A
In the diagram, the circle has centre O. ⌅ Chords A chord of a circle is a line segment with
D
endpoints on the circle; e.g. line segment AB in the diagram. A chord passing through the centre of the circle is called a diameter; e.g. line segment CD in the diagram.
C
O B
⌅ Arcs Any two points on a circle divide the circle into arcs. The shorter arc is called the
minor arc and the longer is the major arc. In the diagram, arc ACB is a minor arc and arc ADB is a major arc. The arcs DAC and DBC are called semicircular arcs. ⌅ Segments Every chord divides the interior of a circle into two regions called segments.
The smaller is called the minor segment and the larger is the major segment. In the above diagram, the minor segment has been shaded. A
⌅ Sectors Two radii and an arc define a region called a
sector. In this diagram, with circle centre O, the shaded region is a minor sector and the unshaded region is a major sector.
D
C
O B
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404 Chapter 13: Trigonometric ratios and applications
I Arc length
A
The circle in the diagram has centre O and radius r. The arc ACB and the corresponding chord AB are said to subtend the angle \AOB at the centre of the circle.
r O θ°
D
C
The magnitude ✓ of angle \AOB is a fraction of 360 . The length ` of arc ACB will be the same fraction of the circumference of the circle, 2⇡r.
B
Length of an arc using degrees
`= =
✓ ⇥ 2⇡r 360 ⇡r✓ 180
(where ✓ is measured in degrees)
Radian measure of angles is introduced in Mathematical Methods Units 1 & 2. We recall that, in the unit circle, an arc of length ✓ units subtends an angle of ✓ radians at the centre. A circle of radius r is similar to the unit circle, with similarity factor r, and therefore an arc of length r✓ units subtends an angle of ✓ radians at the centre. Length of an arc using radians
` = r✓
(where ✓ is measured in radians)
Note: As there are 2⇡ radians in a circle, the arc length is ` =
✓ ⇥ 2⇡r = r✓. 2⇡
I Chord length In triangle OAP: AP = r sin )
A
✓✓◆
O
r
2 ✓✓◆ AB = 2r sin 2
O θ
θ 2
r B
B
r A
P
I Area of a sector The magnitude ✓ of angle \AOB is a fraction of 360 . The area of the sector will be the same fraction of the area of the circle, ⇡r2 . Using degrees:
Area of sector =
⇡r2 ✓ 360
Using radians:
Area of sector =
1 2 r ✓ 2
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A r O θ° B
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13E Circle mensuration 405
Example 9 The circle shown has centre O and radius length 10 cm. The angle subtended at O by arc ACB has magnitude 120 . Find: i the exact length of the chord AB ii the exact length of the arc ACB b the exact area of the minor sector AOB c the magnitude of angle AOC, in degrees, if the minor arc AC has length 4 cm.
A 10 cm
a
C
O 120° 10 cm B
Solution a
✓✓◆ i Chord length = 2r sin 2
= 20 sin 60 since r = 10 and ✓ = 120 p 3 = 20 ⇥ p 2 = 10 3 p Length of chord is 10 3 cm.
ii Arc length ` = r✓ 2⇡ = 10 ⇥ 3 20⇡ = 3
using radians since r = 10 and ✓ =
2⇡ 3
20⇡ cm. 3 Check: Verify that length of arc is greater than length of chord. Length of arc is
1 2 r ✓ using radians 2 1 2⇡ 2⇡ = ⇥ 102 ⇥ since r = 10 and ✓ = 2 3 3 100⇡ = 3 100⇡ Area of minor sector AOB is cm2 . 3 c Using radians: ` = r✓
b Area of sector =
)
A 10 cm
4 = 10✓ 4 ✓= 10
O
θ
4 cm C
180 ⇡ = (22.9183 . . . )
Convert to degrees: \AOC = 0.4 ⇥
= 22.92
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
(correct to two decimal places)
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406 Chapter 13: Trigonometric ratios and applications
I Area of a segment The area of the shaded segment is found by subtracting the area of 4AOB from the area of the minor sector OAB. 2
Using degrees:
Area of segment =
⇡r ✓ 360
1 2 r sin ✓ 2
Using radians:
Area of segment =
1 2 r ✓ 2
1 2 r sin ✓ 2
A r O θ° B
Example 10 A circle, with centre O and radius length 20 cm, has a chord AB that is 10 cm from the centre of the circle. Calculate the area of the minor segment formed by this chord. Solution 1 The area of the segment is r2 (✓ sin ✓). We know r = 20, but we need to find ✓. 2 ✓ ✓ ◆ 10 C In 4OCB: cos = A B 2 20 θ 10 cm ✓ ⇡ 20 cm = O 2 3 2⇡ ) ✓= 3 ✓ 2⇡ ⇣ 2⇡ ⌘◆ 1 Area of segment = ⇥ 202 sin 2 3 3 ✓ 2⇡ p3 ◆ = 200 3 2 ✓ 4⇡ 3p3 ◆ = 200 6 p 100(4⇡ 3 3) = cm2 3
Section summary ⌅ Circle mensuration formulas with ✓ in radians • Arc length = r✓
1 • Area of sector = r2 ✓ 2
• Chord length = 2r sin
2 1 2 • Area of segment = r (✓ 2
⌅ Circle mensuration formulas with ✓ in degrees
⇡r✓ 180 ⇡r2 ✓ • Area of sector = 360 • Arc length =
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
✓✓◆
• Chord length = 2r sin
✓✓◆
2 ⇡r2 ✓ • Area of segment = 360
sin ✓)
1 2 r sin ✓ 2
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13E Circle mensuration 407
13E
Exercise 13E Skillsheet
1
Find the length of an arc which subtends an angle of magnitude 105 at the centre of a circle of radius length 25 cm.
2
Find the magnitude, in degrees, of the angle subtended at the centre of a circle of radius length 30 cm by:
Example 9
a an arc of length 50 cm b a chord of length 50 cm. Example 10
3
A chord of length 6 cm is drawn in a circle of radius 7 cm. Find: a the length of the minor arc cut o↵ by the chord b the area of the smaller region inside the circle cut o↵ by the chord.
4
Sketch, on the same set of axes, the graphs of A = { (x, y) : x2 + y2 16 } and B = { (x, y) : y 2 }. Find the area measure of the region A \ B.
5
Find the area of the region between an equilateral triangle of side length 10 cm and the circumcircle of the triangle (the circle that passes through the three vertices of the triangle).
6
A person stands on level ground 60 m from the nearest point of a cylindrical tank of radius length 20 m. Calculate: a the circumference of the tank b the percentage of the circumference that is visible to the person.
7
The minute hand of a large clock is 4 m long. a How far does the tip of the minute hand move between 12:10 p.m. and 12:35 p.m.? b What is the area covered by the minute hand between 12:10 p.m. and 12:35 p.m.?
8
Two circles of radii 3 cm and 4 cm have their centres 5 cm apart. Calculate the area of the region common to both circles.
9
A sector of a circle has perimeter 32 cm and area 63 cm2 . Find the radius length and the magnitude of the angle subtended at the centre of the two possible sectors.
10
Two wheels (pulleys) have radii of length 15 cm and 25 cm and have their centres 60 cm apart. What is the length of the belt required to pass tightly around the pulleys without crossing?
11
A frame in the shape of an equilateral triangle encloses three circular discs of radius length 5 cm so that the discs touch each other. Find: a the perimeter of the smallest frame which can enclose the discs b the area enclosed between the discs.
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408 Chapter 13: Trigonometric ratios and applications
13F Angles of elevation, angles of depression and bearings The angle of elevation is the angle between the horizontal and a direction above the horizontal.
ht f sig o e lin angle of elevation
eye level
The angle of depression is the angle between the horizontal and a direction below the horizontal.
eye level angle of depression line of s igh t
cliff
Example 11 The pilot of a helicopter flying at 400 m observes a small boat at an angle of depression of 1.2 . Calculate the horizontal distance of the boat to the helicopter. Solution AH = tan 1.2 AB
)
H
400 = tan 1.2 AB
400 m
400 tan 1.2
A
AB =
1.2° (angle of depression)
(diagram not to scale)
B
= 19 095.800 . . . The horizontal distance is 19 100 m, correct to the nearest 10 m.
Example 12 The light on a cli↵-top lighthouse, known to be 75 m above sea level, is observed from a boat at an angle of elevation of 7.1 . Calculate the distance of the boat from the lighthouse. Solution
L
75 = tan 7.1 AB )
75 AB = tan 7.1
75 m A
7.1°
B
= 602.135 . . . The distance of the boat from the lighthouse is 602 m, correct to the nearest metre.
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13F Angles of elevation, angles of depression and bearings 409
Example 13 From the point A, a man observes that the angle of elevation of the summit of a hill is 10 . He then walks towards the hill for 500 m along flat ground. The summit of the hill is now at an angle of elevation of 14 . Find the height of the hill above the level of A. Solution Magnitude of \HBA = (180
14) = 166
Magnitude of \AHB = 180
(166 + 10)
H
=4
4° 166°
Using the sine rule in triangle ABH: 500 HB = sin 4 sin 10 )
HB =
10° 500 m
A
B
14°
C
500 sin 10 sin 4
= 1244.67 . . . In triangle BCH: HC = sin 14 HB )
HC = HB sin 14 = 301.11 . . .
The height of the hill is 301 m, correct to the nearest metre.
I Bearings The bearing (or compass bearing) is the direction measured from north clockwise. For example:
N
⌅ The bearing of A from O is 030 .
A
D
⌅ The bearing of B from O is 120 .
30°
⌅ The bearing of C from O is 210 .
120°
⌅ The bearing of D from O is 330 .
O 330°
W
E 210°
B
C S
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410 Chapter 13: Trigonometric ratios and applications Example 14 The road from town A runs due west for 14 km to town B. A television mast is located due south of B at a distance of 23 km. Calculate the distance and bearing of the mast from the centre of town A. Solution
N
23 tan ✓ = 14 ✓ = 58.67
)
B
(to two decimal places)
Thus the bearing is 180 + (90
14 km θ
A
23 km
58.67) = 211.33
To find the distance, use Pythagoras’ theorem: T
AT 2 = AB2 + BT 2 = 142 + 232 = 725 )
AT = 26.925 . . .
The mast is 27 km from the centre of town A (to the nearest kilometre) and on a bearing of 211.33 .
Example 15 A yacht starts from a point A and sails on a bearing of 038 for 3000 m. It then alters its course to a bearing of 318 and after sailing for a further 3300 m reaches a point B. Find: a the distance AB b the bearing of B from A. Solution a The magnitude of angle ACB needs to be found so that the cosine rule can be applied in triangle ABC: \ACB = (180
B 3300 m
(38 + 42)) = 100
In triangle ABC: 2
42° 2
AB = 3000 + 3300
2
2 ⇥ 3000 ⇥ 3300 cos 100
C 318°
= 23 328 233.917 . . . )
N
N 38°
AB = 4829.931 . . .
The distance of B from A is 4830 m (to the nearest metre).
3000 m
A
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13F Angles of elevation, angles of depression and bearings 411
13F
b To find the bearing of B from A, the magnitude of angle BAC must first be found. Using the sine rule: 3300 AB = sin A sin 100 )
)
B
N
3300 sin 100 AB = 0.6728 . . .
42°
sin A =
C
A = (42.288 . . . )
The bearing of B from A = 360
(42.29
N 38°
38 )
= 355.71 The bearing of B from A is 356 to the nearest degree.
38°
A
Exercise 13F Example 11
1
From the top of a vertical cli↵ 130 m high, the angle of depression of a buoy at sea is 18 . What is the distance of the buoy from the foot of the cli↵?
Example 12
2
The angle of elevation of the top of an old chimney stack at a point 40 m from its base is 41 . Find the height of the chimney.
3
A hiker standing on top of a mountain observes that the angle of depression to the base of a building is 41 . If the height of the hiker above the base of the building is 500 m, find the horizontal distance from the hiker to the building.
4
A person lying down on top of a cli↵ 40 m high observes the angle of depression to a buoy in the sea below to be 20 . If the person is in line with the buoy, find the distance between the buoy and the base of the cli↵, which may be assumed to be vertical.
Example 13
5
A person standing on top of a cli↵ 50 m high is in line with two buoys whose angles of depression are 18 and 20 . Calculate the distance between the buoys.
Example 14
6
A ship sails 10 km north and then sails 15 km east. What is its bearing from the starting point?
7
A ship leaves port A and travels 15 km due east. It then turns and travels 22 km due north. a What is the bearing of the ship from port A? b What is the bearing of port A from the ship?
Example 15
8
A yacht sails from point A on a bearing of 035 for 2000 m. It then alters course to a direction with a bearing of 320 and after sailing for 2500 m it reaches point B. a Find the distance AB.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b Find the bearing of B from A.
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412 Chapter 13: Trigonometric ratios and applications 9
13F
The bearing of a point A from a point B is 207 . What is the bearing of B from A?
10
The bearing of a ship S from a lighthouse A is 055 . A second lighthouse B is due east of A. The bearing of S from B is 302 . Find the magnitude of angle ASB.
11
A yacht starts from L and sails 12 km due east to M. It then sails 9 km on a bearing of 142 to K. Find the magnitude of angle MLK.
12
The bearing of C from A is 035 . The bearing of B from A is 346 . The distance of C from A is 340 km. The distance of B from A is 160 km.
N B
13
340 km
160 km 35°
a Find the magnitude of angle BAC. b Use the cosine rule to find the distance from B to C.
C
A
346°
From a ship S , two other ships P and Q are on bearings 320 and 075 respectively. The distance PS is 7.5 km and the distance QS is 5 km. Find the distance PQ.
13G Problems in three dimensions Some problems in three dimensions can be solved by picking out triangles from a main figure and finding lengths and angles through these triangles.
Example 16 H
ABCDEFGH is a cuboid. Find: a b c d
the distance DB the distance HB the magnitude of angle HBD the magnitude of angle HBA.
G
E
F
7 cm
D
A
10 cm
B
C 8 cm
Solution a
DB2 = 82 + 102
D
= 164 p ) DB = 164
8 cm
= 12.81 cm b
A
(correct to two decimal places)
HB2 = HD2 + DB2
10 cm
B
H
2
= 7 + 164
7 cm
= 213 p ) HB = 213
D
= 14.59 cm Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
q° √164 cm
B
(correct to two decimal places)
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13G Problems in three dimensions 413
HD BD 7 = p 164
c tan ✓ =
H 7 cm
) ✓ = 28.66
q° √164 cm
D
(correct to two decimal places)
d From triangle HBA:
B
H
10 cos B = p 213
√213 cm
) B = 46.75
(correct to two decimal places)
A
10 cm
B
Example 17 The figure shows a pyramid with a square base. The base has sides 6 cm long and the edges V A, V B, VC and V D are each 10 cm long. a b c d
V
10 cm
Find the length of DB. Find the length of BE. Find the length of V E. Find the magnitude of angle V BE.
A D
B E
6 cm
C
Solution a
DB2 = 62 + 62
A
= 72 p ) DB = 6 2
6 cm
E
= 8.4852 . . .
D
V E 2 = V B2 = 102
BE 2 p 3 2
= 100
18
The length of BE is 4.24 cm, correct to two decimal places. VE VB p 82 = 10
d sin ✓ =
V 2
10 cm
= 82 p ) V E = 82
= 0.9055 . . .
= 9.0553 . . . The length of V E is 9.06 cm, correct to two decimal places.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
= 4.2426 . . .
C
6 cm
The length of DB is 8.49 cm, correct to two decimal places. c
1 DB 2 p =3 2
b BE =
B
E
θ°
B
) ✓ = (64.8959 . . . ) The magnitude of \V BE is 64.90 , correct to two decimal places.
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414 Chapter 13: Trigonometric ratios and applications
13G
Example 18 H
A communications mast is erected at corner A of a rectangular courtyard ABCD with side lengths 60 m and 45 m as shown. If the angle of elevation of the top of the mast from C is 12 , find: a the height of the mast b the angle of elevation of the top of the mast from B. Solution
A
a AC 2 = 452 + 602 = 5625 )
C
60 m
)
45 m
H
) ✓ = (19.507 . . . ) θ°
B H
HA = 75 tan 12 = 15.941 . . . C
12° 75 m
B
60 m
HA 45 = 0.3542 . . .
B
HA = tan 12 75
C
A
b tan ✓ =
45 m
AC = 75
D
12°
A
45 m
The angle of elevation of the top of the mast, H, from B is 19.51 , correct to two decimal places.
A
The height of the mast is 15.94 m, correct to two decimal places.
Exercise 13G Example 16
1
ABCDEFGH is a cuboid with dimensions as shown. Find: a the length of FH
b the length of BH
c the magnitude of angle BHF d the magnitude of angle BHG. Example 17
2
A D 8 cm H
E
the length of EF the magnitude of angle V EF the length of V E the length of a sloping edge the magnitude of angle V AD the surface area of the pyramid.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
F 5 cm
G
12 cm
V ABCD is a right pyramid with a square base. The sides of the base are 8 cm in length. The height, V F, of the pyramid is 12 cm. If E is the midpoint of AD, find: a b c d e f
B
C
V
C
D F
E A
8 cm
B
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13G Problems in three dimensions 415
13G Example 18
3
4
A tree stands at a corner of a square playing field. Each side of the square is 100 m long. At the centre of the field, the tree subtends an angle of 20 . What angle does it subtend at each of the other three corners of the field?
A
100 m B
b the height XB.
C
100 m
Suppose that A, C and X are three points in a horizontal plane and that B is a point vertically above X. The length of AC is 85 m and the magnitudes of angles BAC, ACB and BCX are 45 , 90 and 32 respectively. Find: a the distance CB
T
20°
B
X 32° 45° 85 m
A
C
5
Standing due south of a tower 50 m high, the angle of elevation of the top is 26 . What is the angle of elevation after walking a distance 120 m due east?
6
From the top of a cli↵ 160 m high, two buoys are observed. Their bearings are 337 and 308 . Their respective angles of depression are 3 and 5 . Calculate the distance between the buoys. H
7
Find the magnitude of each of the following angles for the cuboid shown: a ACE
b HDF
c ECH
E 6 cm A
F D 12 cm
B
C 5 cm
8
From a point A due north of a tower, the angle of elevation to the top of the tower is 45 . From point B, which is 100 m from A on a bearing of 120 , the angle of elevation is 26 . Find the height of the tower.
9
A and B are two positions on level ground. From an advertising balloon at a vertical height of 750 m, point A is observed in an easterly direction and point B at a bearing of 160 . The angles of depression of A and B, as viewed from the balloon, are 40 and 20 respectively. Find the distance between A and B.
10
A right pyramid, height 6 cm, stands on a square base of side length 5 cm. Find: a the length of a sloping edge
11
G
b the area of a triangular face.
A light aircraft flying at a height of 500 m above the ground is sighted at a point A0 due east of an observer at a point O on the ground, measured horizontally to be 1 km from the plane. The aircraft is flying south-west (along A0 B0 ) at 300 km/h.
O¢ 1000 m A¢ O
45°
A
B¢ 500 m B
a How far will it travel in one minute? b Find its bearing from O (O0 ) at this time. c What will be its angle of elevation from O at this time? Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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416 Chapter 13: Trigonometric ratios and applications
13H Angles between planes and more difficult 3D problems A
I Angles between planes Consider any point P on the common line of two planes ⇧1 and ⇧2 . If lines PA and PB are drawn at right angles to the common line so that PA is in ⇧1 and PB is in ⇧2 , then \APB is the angle between planes ⇧1 and ⇧2 .
P1 P
θ
P2
B A
Note: If the plane ⇧2 is horizontal, then PA
is called a line of greatest slope in the plane ⇧1 .
P1 P2 P
angle of lines of greatest slope greatest slope
Example 19 D¢
For the cuboid shown in the diagram, find:
D
a the angle between AC 0 and the plane ABB0A0 b the angle between the planes ACD0 and DCD0 .
A
0
D
We drop a perpendicular from C to the plane (line C B ), and join the foot of the perpendicular to A (line B0 A).
A
A¢ q 3a
3a
B
A¢
B¢ B¢ 3a
A
3a
B C¢ a
q
A
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
B¢
C¢ a
C
Draw separate diagrams showing the base and the section through A, C 0 and B0 . Then we see that p p AB0 = (3a)2 + (3a)2 = 3a 2 a 1 and tan ✓ = p = p 3a 2 3 2 Hence the required angle, ✓, is 13.26 .
D¢
A
B
3a
The required angle, ✓, lies between C 0 A and B0 A.
Then MD is perpendicular to CD0 in the plane DCD0 , and MA is perpendicular to CD0 in the plane ACD0 .
3a
D¢
0 0
D
a
C
A¢
Solution a To find the angle ✓ between AC 0 and the plane ABB0A0 , we need the projection of AC 0 in the plane.
b The line common to the planes ACD0 and DCD0 is CD0 . Let M be the midpoint of the line segment CD0 .
C¢
j
B¢ C¢
M C
B¢
A¢ 3a
a
B
3a
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13H Angles between planes and more difficult 3D problems 417
Thus ' is the angle between the planes DCD0 and ACD0 . We have 1 1 p DM = DC 0 = 3a 2 2 2 p ✓ 3a 2 ◆ p2 ) tan ' = a ÷ = 2 3
D
j
M
A
Hence the required angle is ' = 25.24 .
Example 20 Three points A, B and C are on a horizontal line such that AB = 70 m and BC = 35 m. The angles of elevation of the top of a tower are ↵, and , where 1 1 1 tan ↵ = , tan = , tan = 13 15 20 as shown in the diagram.
P
a
A
Solution Let the height of the tower, PQ, be h m. Then 13h
which implies that QC = 20h
g B
35 m
C
Q
h = QA tan ↵ = QB tan = QC tan QB = 15h,
b
70 m
The base of the tower is at the same level as A, B and C. Find the height of the tower.
QA = 13h,
Q
A
Now consider the base triangle ACQ.
20h 15h q 70 m
B
35 m
C
Using the cosine rule in 4AQB: cos ✓ =
(70)2 + (15h)2 (13h)2 2(70)(15h)
Using the cosine rule in 4CQB: cos ✓ = cos(180
✓) =
(35)2 + (15h)2 (20h)2 2(35)(15h)
Hence (70)2 + (15h)2 (13h)2 (20h)2 (15h)2 (35)2 = 2(70)(15h) 2(35)(15h) 4900 + 56h2 = 2(175h2
1225)
7350 = 294h2 )
h=5
The height of the tower is 5 m. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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418 Chapter 13: Trigonometric ratios and applications Example 21 A sphere rests on the top of a vertical cylinder which is open at the top. The inside diameter of the cylinder is 8 cm. The sphere projects 8 cm above the top of the cylinder. Find the radius length of the sphere. Solution This 3D problem can be represented by a 2D diagram without loss of information. Let the radius length of the sphere be r cm. Then, in 4OBC, we have OC = (8
r) cm,
BC = 4 cm,
OB = r cm
A
Using Pythagoras’ theorem: (8 64
8 cm
O C
B
r)2 + 42 = r2
16r + r2 + 16 = r2 8 cm
16r + 80 = 0 )
r=5
The radius length of the sphere is 5 cm.
Example 22 A box contains two standard golf balls that fit snugly inside. The box is 85 mm long. What percentage of the space inside the box is air? Solution Two 2D diagrams may be used to represent the 3D situation.
side view
end view
Let r mm be the radius length of a golf ball. Length of box = 85 mm = 4r mm 85 Thus r = , i.e. r = 21.25 4
85 mm
So the box has dimensions 85 mm by 42.5 mm by 42.5 mm. Now
volume of box = 42.52 ⇥ 85 volume of two golf balls = 2 ⇥ =
Hence
percentage air =
8 ⇡ ⇥ 21.253 3
100 42.52 ⇥ 85
= 47.6%
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
4 ⇥ ⇡ ⇥ 21.253 3
8 3⇡
42.52 ⇥ 85
using V = Ah 4 using V = ⇡r3 3
⇥ 21.253
to one decimal place
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13H Angles between planes and more difficult 3D problems 419
13H
Exercise 13H Example 19
1
The diagram shows a rectangular prism. Assume that AB = 4a units, BC = 3a units, GC = a units. a Calculate the areas of the faces ABFE, BCGF and ABCD.
H
G
E
F D
C B
A
b Calculate the magnitude of the angle which plane GFAD makes with the base. c Calculate the magnitude of the angle which plane HGBA makes with the base. d Calculate the magnitude of the angle which AG makes with the base. 2
V ABCD is a right pyramid with square base ABCD, and with AB = 2a and OV = a. a Find the slope of the edge V A. That is, find the magnitude of \V AO. b Find the slope of the face V BC.
3
D A
C O
B
F
5 A hill has gradient . If BF makes an angle of 45 with 12 the line of greatest slope, find: a the gradient of BF b the magnitude of \FBD.
4
V
E 5 C
D 12 A
B
The cross-section of a right prism is an isosceles triangle ABC with AB = BC = 16 cm and \ABC = 58 . The equal edges AD, BE and CF are parallel and of length 12 cm. Calculate: a the length of AC b the length of AE c the magnitude of the angle between AE and EC.
Example 20
5
A vertical tower, AT , of height 50 m, stands at a point A on a horizontal plane. The points A, B and C lie on the same horizontal plane, where B is due west of A and C is due south of A. The angles of elevation of the top of the tower, T , from B and C are 25 and 30 respectively. a Giving answers to the nearest metre, calculate the distances: i AB ii AC iii BC b Calculate the angle of elevation of T from the midpoint, M, of AB.
6
A right square pyramid, vertex O, stands on a square base ABCD. The height is 15 cm and the base side length is 10 cm. Find: a b c d
the length of the slant edge the inclination of a slant edge to the base the inclination of a sloping face to the base the magnitude of the angle between two adjacent sloping faces.
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420 Chapter 13: Trigonometric ratios and applications
13H
7
A post stands at one corner of a rectangular courtyard. The elevations of the top of the post from the nearest corners are 30 and 45 . Find the elevation from the diagonally opposite corner.
8
V ABC is a regular tetrahedron with base 4ABC. (All faces are equilateral triangles.) Find the magnitude of the angle between: a a sloping edge and the base b adjacent sloping faces.
9
10
An observer at a point A at sea level notes an aircraft due east at an elevation of 35 . At the same time an observer at B, which is 2 km due south of A, reports the aircraft on a bearing of 50 . Calculate the altitude of the aircraft. ABFE represents a section of a ski run which has a uniform inclination of 30 to the horizontal, with AE = 100 m and AB = 100 m. A skier traverses the slope from A to F. Calculate: a the distance that the skier has traversed b the inclination of the skier’s path to the horizontal.
A
B
D
C
E
F
Example 21
11
A sphere of radius length 8 cm rests on the top of a hollow inverted cone of height 15 cm whose vertical angle is 60 . Find the height of the centre of the sphere above the vertex of the cone.
Example 22
12
Four congruent spheres, radius length 10 cm, are placed on a horizontal table so that each touches two others and their centres form a square. A fifth congruent sphere rests on top of them. Find the height of the top of this fifth sphere above the table.
13
A cube has edge length a cm. What is the radius length, in terms of a, of: a the sphere that just contains the cube b the sphere that just fits inside the cube?
14
In the diagram, the edge AB is vertical, 4 BCD is horizontal, \CBD is a right angle and AB = 20 m, BD = 40 m, BC = 30 m. Calculate the inclination to the horizontal of: a AD b AE, where AE is the line of greatest slope c AE, where E is the midpoint of CD.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
A
B C
D E
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Chapter 13 review 421
Review
Chapter summary Triangles AS Nrich
⌅ Labelling triangles • Interior angles are denoted by uppercase letters.
B
• The length of the side opposite an angle is denoted by the
a
c
corresponding lowercase letter.
A
For example, the magnitude of angle BAC is denoted by A, and the length of side BC by a. ⌅ Sine rule
B
For triangle ABC: a b c = = sin A sin B sin C
C
b
a
c A
C
b
The sine rule is used to find unknown quantities in a triangle in the following cases: • one side and two angles are given
• two sides and a non-included angle are given.
In the first case, the triangle is uniquely defined. But in the second case, there may be two triangles. ⌅ Cosine rule
B
For triangle ABC: a2 = b2 + c2 cos A =
a
c
2bc cos A
A
C
b
b2 + c2 a2 2bc
The symmetrical results also hold: b2 = a2 + c2 2
2
c =a +b
2
2ac cos B 2ab cos C
The cosine rule is used to find unknown quantities in a triangle in the following cases: • two sides and the included angle are given • three sides are given. ⌅ Area of a triangle
Area =
1 bh 2
Area =
1 bc sin A 2
B c A
h b
a C
That is, the area of a triangle is half the product of the lengths of two sides and the sine of the angle included between them.
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Review
422 Chapter 13: Trigonometric ratios and applications Circles ⌅ Length of minor arc AB (red curve) is given by
A
` = r✓
r
⌅ Area of sector AOB (shaded) is given by
Area =
qc
O
ℓ
1 2 r ✓ 2
B
⌅ Length of chord AB (red line) is given by
` = 2r sin
A
✓✓◆
r
2
Area =
1 2 r (✓ 2
qc
O
⌅ Area of segment (shaded) is given by
sin ✓)
B
Angle between planes ⌅ Consider any point P on the common line of two planes ⇧1 and ⇧2 . If lines PA and PB are drawn at right angles to the common line so that PA is in ⇧1 and PB is in ⇧2 , then \APB is the angle between ⇧1 and ⇧2 .
A P1 P P2
θ B
⌅ If plane ⇧2 is horizontal, then PA is called
A
a line of greatest slope in plane ⇧1 . P1 P2 P
angle of lines of greatest slope greatest slope
Technology-free questions 1
a Find x. b Find y.
B 10 cm A
2
30°
y° x cm
a Find AH, where AH is the altitude. b Find CM, where CM is the median.
C A
30° B
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
6 cm
40 cm
40 cm
C
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Chapter 13 review 423
From a port P, a ship Q is 20 km away on a bearing of 112 , and a ship R is 12 km away on a bearing of 052 . Find the distance between the two ships.
4
In a quadrilateral ABCD, AB = 5 cm, BC = 5 cm, CD = 7 cm, B = 120 and C = 90 . Find: a the length of the diagonal AC c the area of triangle ADC
b the area of triangle ABC d the area of the quadrilateral.
5
If sin x = sin 37 and x is obtuse, find x.
6
A point T is 10 km due north of a point S . A point R, which is east of the straight line joining T and S , is 8 km from T and 7 km from S . Calculate the cosine of the bearing of R from S .
7
In 4ABC, AB = 5 cm, \BAC = 60 and AC = 6 cm. Calculate the sine of \ABC.
8
The area of a sector of a circle with radius 6 cm is 33 cm2 . Calculate the angle of the sector.
9
The diagram shows two survey points, A and B, which are on an east–west line on level ground. From point A, the bearing of a tower T is 060 , while from point B, the bearing of the tower is 045 . i Find the magnitude of \T AB. ii Find the magnitude of \AT B. p p 6 2 b Given that sin 15 = , find 4 the distances AT and BT .
Review
3
N
N
T
a
60° A
45° 300 m
B
10
A boat sails 11 km from a harbour on a bearing of 220 . It then sails 15 km on a bearing of 340 . How far is the boat from the harbour?
11
A helicopter leaves a heliport A and flies 2.4 km on a bearing of 150 to a checkpoint B. It then flies due east to its base C. a If the bearing of C from A is 120 , find the distances AC and BC. b The helicopter flies at a constant speed throughout and takes five minutes to fly from A to C. Find its speed.
12
A sector of a circle has an arc length of 30 cm. If the radius of the circle is 12 cm, find the area of the sector.
13
A chord PQ of a circle, radius 5 cm, subtends an angle of 2 radians at the centre of the circle. Taking ⇡ to be 3.14, calculate the length of the major arc PQ, correct to one decimal place.
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Review
424 Chapter 13: Trigonometric ratios and applications 14
The diagram shows a circle of radius length 13 cm and a chord AB of length 24 cm. Calculate:
C
A 24
a the length of arc ACB b the area of the shaded region.
13 O
15
13
B
From a cli↵ top 11 m above sea level, two boats are observed. One has an angle of depression of 45 and is due east, the other an angle of depression of 30 on a bearing of 120 . Calculate the distance between the boats.
Multiple-choice questions 1
In a triangle XYZ, x = 21 cm, y = 18 cm and \Y XZ = 62 . The magnitude of \XYZ, correct to one decimal place, is A 0.4
2
6
E 53.1
B 10
C 11
D 81
E 129
B 63
C 74
D 82
E 98
The area of the triangle ABC, where b = 5 cm, c = 3 cm, \A = 30 and \B = 70 , is A 2.75 cm2
5
D 49.2
In a triangle ABC, a = 5.2 cm, b = 6.8 cm and c = 7.3 cm. The magnitude of \ACB, correct to the nearest degree, is A 43
4
C 1.0
51 In a triangle ABC, a = 30, b = 21 and cos C = . The value of c, to the nearest whole 53 number, is A 9
3
B 0.8
B 3.75 cm2
C 6.5 cm2
D 7.5 cm2
E 8 cm2
The length of the radius of the circle shown, correct to two decimal places, is A 5.52 cm
B 8.36 cm
D 12.18 cm
E 18.13 cm
C 9.01 cm 130° 10 cm
A chord of length 5 cm is drawn in a circle of radius 6 cm. The area of the smaller region inside the circle cut o↵ by the chord, correct to one decimal place, is A 1.8 cm2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
B 2.3 cm2
C 3.9 cm2
D 13.6 cm2
E 15.5 cm2
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Chapter 13 review 425
From a point on a cli↵ 500 m above sea level, the angle of depression to a boat is 20 . The distance from the foot of the cli↵ to the boat, to the nearest metre, is A 182 m
8
C 210 m
D 1374 m
E 1834 m
B 4
C 53
D 86
E 89
A man walks 5 km due east followed by 7 km due south. The bearing he must take to return to the start is A 036
10
B 193 m
A tower 80 m high is 1.3 km away from a point on the ground. The angle of elevation to the top of the tower from this point, correct to the nearest degree, is A 1
9
Review
7
B 306
C 324
D 332
E 348
A boat sails at a bearing of 215 from A to B. The bearing it must take from B to return to A is A 035
B 055
C 090
D 215
E 250
Extended-response questions 1
AB is a tower 60 m high on top of a hill. The magnitude of \ACO is 49 and the magnitude of \BCO is 37 .
A B
a Find the magnitudes of \ACB, \CBO and \CBA. b Find the length of BC. c Find the height of the hill, i.e. the length of OB. 2
C O
The angle of a sector of a circle, centre O and radius length 12 cm, has magnitude 2.5 radians. The sector is folded so that OA and OA0 are joined to form a cone. Calculate:
O 2.5 c
a the base radius length of the cone b the curved surface area of the cone c the shortest distance between two points diametrically opposed on the edge of the base. 3
A
A¢
A tower 110 m high stands on the top of a hill. From a point A at the foot of the hill, the angle of elevation of the bottom of the tower is 7 and that of the top is 10 . a Find the magnitudes of angles T AB, ABT and AT B. b Use the sine rule to find the length of AB. c Find CB, the height of the hill.
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
T 110 m B A
7°
10°
C
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Review
426 Chapter 13: Trigonometric ratios and applications 4
Point S is a distance of 120 m from the base of a building. On the building is an aerial, AB. The angle of elevation from S to A is 57 . The angle of elevation from S to B is 59 . Find:
B A
a the distance OA b the distance OB c the distance AB.
59° S
5
From the top of a communications tower, T , the angles of depression of two points A and B on a horizontal line through the base of the tower are 30 and 40 . The distance between the points is 100 m. Find: a the distance AT b the distance BT c the height of the tower.
6
A
100 m
B
O
T top of tower
base of tower
V
the distance V A the distance VC the distance AC the magnitude of angle VCA.
8 cm 8 cm B 6 cm A
7
120 m
40° 30°
Angles V BA, V BC and ABC are right angles. Find: a b c d
57°
C
The perimeter of a triangle ABC is L metres. Find the area of the triangle in terms of L and the triangle’s angles ↵, and . Hint: Let AB = x. Using the sine rule, first find the other side lengths in terms of x.
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Chapter 14
14
Further trigonometry
Objectives I I I I I I I I I I
To further explore the symmetry properties of circular functions. To further understand and sketch the graphs of circular functions. To solve equations involving circular functions. To evaluate simple trigonometric expressions using trigonometric identities. To prove simple trigonometric identities. To apply the addition formulas for circular functions. To apply the double angle formulas for circular functions. To simplify expressions of the form a cos x + b sin x. To sketch graphs of functions of the form f(x) = a cos x + b sin x. To solve equations of the form a cos x + b sin x = c.
There are many interesting and useful relationships between the trigonometric functions. The most fundamental is the Pythagorean identity: sin2 A + cos2 A = 1 Some of these identities were discovered a very long time ago. For example, the following two results were discovered by the Indian mathematician Bh¯askara II in the twelfth century: sin(A + B) = sin A cos B + cos A sin B cos(A + B) = cos A cos B
sin A sin B
They are of great importance in many areas of mathematics, including calculus. Note: An introduction to sine, cosine and tangent as functions is given in Mathematical
Methods Units 1 & 2 and also in an online chapter for this book, available in the Interactive Textbook. Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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428 Chapter 14: Further trigonometry
14A Symmetry properties In this section we revise symmetry properties and exact values of sine and cosine. Note: sin(2⇡ + ✓) = sin ✓
Quadrant 2 Quadrant 1 By symmetry sin(π − θ) = b = sin θ cos(π − θ) = −a = −cos θ tan(π − θ) = b = −tan θ (0, b) −a P(π − θ)
cos(2⇡ + ✓) = cos ✓ tan(2⇡ + ✓) = tan ✓
P(θ) = (cos θ, sin θ) = (a, b) θ
(−a, 0)
(a, 0)
0
P(2π − θ)
P(π + θ) (0, −b) Quadrant 3 sin(π + θ) = −b = −sin θ cos(π + θ) = −a = −cos θ −b = tan θ tan(π + θ) = −a
Quadrant 4 sin(2π − θ) = −b = −sin θ cos(2π − θ) = a = cos θ tan(2π − θ) = −b a = −tan θ y
Negative angles
1
By symmetry:
P(θ)
cos( ✓) = cos ✓ sin( ✓) = tan( ✓) =
sin ✓ sin ✓ = cos ✓
−1
θ −θ
0
x
1
tan ✓ P(−θ) −1
Exact values of sine and cosine The values in this table can easily be determined from the graphs of sine and cosine or from the unit circle.
✓ sin ✓ cos ✓
⇡
⇡ 2
0
⇡ 2
⇡
3⇡ 2
2⇡
0
1
0
1
0
1
0
1
0
1
The values in this table can easily be determined by drawing: ⌅ an equilateral triangle of side length 2 and
one median ⌅ a square of side length 1 and one diagonal.
0
✓ sin ✓ cos ✓
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1
0
1
⇡ 6
⇡ 4
1 2 p 3 2
1 p 2
⇡ 3 p 3 2
1 p 2
1 2
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14A Symmetry properties 429
14A Complementary relationships From the diagram to the right: ✓⇡ ◆ sin ✓ = a = cos ✓ 2 ✓⇡ ◆ cos ✓ = b = sin ✓ 2
y π −θ 2
P b a
π −θ 2
θ θ
From the diagram to the right: ✓⇡ ◆ sin + ✓ = a = cos ✓ 2 ✓⇡ ◆ cos + ✓ = b = sin ✓ 2
P(θ) b
x
a
y
π P +θ 2 b
π +θ 2
a θ
θ
P(θ) b x
a
Example 1 If sin ✓ = 0.4 and cos ↵ = 0.8, find the value of: ✓⇡ ◆ ✓⇡ ◆ a sin ↵ b cos + ✓ 2 2 Solution ✓⇡ a sin 2
◆ ↵ = cos ↵ = 0.8
b cos
✓⇡ 2
◆ +✓ =
c sin( ✓)
sin ✓
c sin( ✓) =
sin ✓
= 0.4
= 0.4
Exercise 14A 1
Example 1
2
Evaluate each of the following: ✓ 3⇡ ◆ ✓ 5⇡ ◆ ✓ 25⇡ ◆ a cos b sin c sin 4 4 2 ✓ 15⇡ ◆ ✓ 17⇡ ◆ f sin g sin(27⇡) h sin 4 3 ✓ 35⇡ ◆ ✓ 45⇡ ◆ ✓ 16⇡ ◆ k sin l cos m cos 2 6 3
d sin
✓ 15⇡ ◆
i cos
6
✓ 75⇡ ◆
j cos
4
✓ 15⇡ ◆ 6
6 ✓ 105⇡ ◆ n sin o cos(1035⇡) 2
If sin x = 0.3 and cos ↵ = 0.6, find the value of: ✓⇡ ◆ ✓⇡ ◆ a cos( ↵) b sin + ↵ c cos x 2 2 ✓⇡ ◆ ✓⇡ ◆ ✓ 3⇡ ◆ e cos + x f sin ↵ g sin +↵ 2 2 2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
e cos
✓ 17⇡ ◆
d sin( x) h cos
✓ 3⇡ 2
x
◆
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430 Chapter 14: Further trigonometry
14B The tangent function C(1, y) 1
tan ✓ =
)
P(θ)
tan θ sin θ θ A O D 1 cos θ
By considering the similar triangles OPD and OCA: -1
tan ✓ sin ✓ = 1 cos ✓
B
y
Consider the unit circle. If we draw a tangent to the unit circle at A, then the y-coordinate of C, the point of intersection of the line OP and the tangent, is called tangent ✓ (abbreviated to tan ✓).
sin ✓ cos ✓
x
-1
Note that tan ✓ is undefined when cos ✓ = 0. A table of values for y = tan x is given below. x
⇡
3⇡ 4
y
0
1
⇡ 2
⇡ 4
0
⇡ 4
⇡ 2
3⇡ 4
⇡
5⇡ 4
3⇡ 2
7⇡ 4
2⇡
9⇡ 4
5⇡ 2
11⇡ 4
3⇡
ud
1
0
1
ud
1
0
1
ud
1
0
1
ud
1
0
The graph of y = tan x is given below. y
−π −4
−3 −2
−π 2 2 1 −1
−1
π 2 0
1
2
3π 2
π 3
5π 2 2π
4
5
6
3π 7
8
9
10
x
−2
You must also know the following exact values: ✓⇡◆ ✓⇡◆ ✓⇡◆ p 1 tan = p , tan = 1, tan = 3 6 4 3 3
Properties of the tangent function ⌅ The graph repeats itself every ⇡ units, i.e. the period of tan is ⇡. ⌅ The range of tan is R.
(2k + 1)⇡ where k 2 Z. 2 ⌅ The axis intercepts are at x = k⇡ where k 2 Z. ⌅ The vertical asymptotes have equations x =
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14B The tangent function 431
Symmetry Using symmetry properties of sine and cosine, we have tan(⇡
sin(⇡ ✓) sin ✓ = = cos(⇡ ✓) cos ✓
✓) =
tan ✓
Similarly, we obtain: ⌅ tan(⇡ + ✓) = tan ✓
✓) = tan ✓ ⌅ tan( ✓) = ◆ cos ✓ ⌅ tan ⌅ tan + ✓ = 2 2 sin ✓ cos ✓ Note: We will see in Section 14E that can be written as cot ✓. sin ✓ ✓⇡
⌅ tan(2⇡
◆ cos ✓ ✓ = sin ✓
✓⇡
tan ✓
I Solution of equations involving the tangent function We now consider the solution of equations involving the tangent function, which can be applied to finding the x-axis intercepts for graphs of the tangent function.
Example 2 Solve the equation 3 tan(2x) = Solution 3 tan(2x) =
p
3 for x 2 (0, 2⇡).
p
3 p 3 1 tan(2x) = = p 3 3 ⇡ 7⇡ 13⇡ 19⇡ ) 2x = or or or 6 6 6 6 x=
Solve the equation tan
implies
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
⇡ ⌘◆ 4
1✓ x 2
Once we have found one solution for 2x, we can obtain all other solutions by adding and subtracting multiples of ⇡.
⇡ 7⇡ 13⇡ 19⇡ or or or 12 12 12 12
Example 3
Solution ✓1⇣ tan x 2
Explanation Since we want solutions for x in (0, 2⇡), we find solutions for 2x in (0, 4⇡).
✓1⇣ 2
x
⇡ ⌘◆ = 1 for x 2 [ 2⇡, 2⇡]. 4
= 1
⇡◆ ⇡ 3⇡ = or 4 4 4
x
⇡ ⇡ 3⇡ = or 4 2 2
)
x=
Explanation Note that
⇡ 9⇡ 7⇡ 2 , 4 4 4 1✓ ⇡ ◆ 9⇡ 7⇡ , x 2 , 2 4 8 8
x 2 [ 2⇡, 2⇡] , x
⇡ 7⇡ or 4 4
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432 Chapter 14: Further trigonometry Graphing the tangent function When graphing a transformation of the tangent function: ⌅ Find the period. ⌅ Find the equations of the asymptotes. ⌅ Find the intercepts with the axes.
Example 4 Sketch the graph of each of the following for x 2 [ ⇡, ⇡]: a y = 3 tan(2x)
b y = 2 tan(3x)
Solution a Period =
⇡ ⇡ = n 2
Asymptotes: x =
b Period = (2k + 1)⇡ , k2Z 4
Axis intercepts: x =
⇡ ⇡ = n 3
Asymptotes: x =
k⇡ , k2Z 2
Axis intercepts: x =
y x=
-π
-π -3π x= 4 4 0
-π 2
(2k + 1)⇡ , k2Z 6 k⇡ , k2Z 3
y x=
π 4
π 2
x=
3π 4
π
x
-π -2π -π 3 3
0
π 3
2π 3
π
x
π π -5π -π -π 5π x= x= x= x= x= x= 6 6 2 6 2 6
Section summary ⌅ The tangent function is given by tan ✓ = ⌅ The graph of y = tan x:
sin ✓ for cos ✓ , 0. cos ✓
• The period is ⇡.
(2k + 1)⇡ where k 2 Z. 2 • The axis intercepts are at x = k⇡ where k 2 Z. • The vertical asymptotes have equations x =
⌅ Useful symmetry properties: • tan(⇡ + ✓) = tan ✓ • tan( ✓) =
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
tan ✓
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14C Reciprocal functions and the Pythagorean identity 433
14B
Exercise 14B Example 2
1
Solve each of the following equations for x in the stated interval: p a tan x = 1, x 2 (0, 2⇡) b tan x = 3, x 2 (0, 2⇡) 1 c tan x = p , x 2 (0, 2⇡) d tan(2x) = 1, x 2 ( ⇡, ⇡) 3 p 1 e tan(2x) = 3, x 2 ( ⇡, ⇡) f tan(2x) = p , x 2 ( ⇡, ⇡) 3
Example 3
2
Example 4
3
Solve each of the following equations for x in the stated interval: ✓ ⇣ ✓ ⇣ ⇡ ⌘◆ ⇡ ⌘◆ a tan 2 x = 1, x 2 (0, 2⇡) b tan 2 x = 1, x 2 ( ⇡, ⇡) 4 4 ✓ ⇣ ✓1⇣ ⇡ ⌘◆ p ⇡ ⌘◆ 1 c tan 3 x = 3, x 2 ( ⇡, ⇡) d tan x = p , x 2 ( ⇡, ⇡) 6 2 6 3 Sketch the graph of each of the following: a y = tan(2x)
b y = tan(3x)
c y=
d y = 3 tan x ✓ ⇡◆ f y = 2 tan x + 4 ✓ ⇡◆ h y = 2 tan x + +1 2
tan(2x) ✓ x◆ e y = tan 2
g y = 3 tan x + 1 ✓ ⇣ ⇡ ⌘◆ i y = 3 tan 2 x 4
2
14C Reciprocal functions and the Pythagorean identity In this section we introduce the reciprocals of the basic trigonometric functions. The graphs of these functions appear in Chapter 15, where reciprocal functions are studied in general. Here we use these functions in various forms of the Pythagorean identity.
I Reciprocal functions The circular functions sine, cosine and tangent can be used to form three other functions, called the reciprocal circular functions. Secant, cosecant and cotangent ⌅ sec ✓ =
1 cos ✓
(for cos ✓ , 0)
⌅ cosec ✓ =
1 sin ✓
(for sin ✓ , 0)
Note: For cos ✓ , 0 and sin ✓ , 0, we have cot ✓ =
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
⌅ cot ✓ =
cos ✓ sin ✓
(for sin ✓ , 0) 1 1 and tan ✓ = . tan ✓ cot ✓
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434 Chapter 14: Further trigonometry Example 5 Find the exact value of each of the following: ✓ 2⇡ ◆ ✓ 5⇡ ◆ a sec b cot 3 4 Solution ✓ 2⇡ ◆ a sec = 3
1 ⇣ 2⇡ ⌘ cos 3 1 = ⇣ ⇡⌘ cos ⇡ 3 1 = ⇣⇡⌘ cos 3 ✓ 1◆ =1÷ 2 = 2
b cot
✓ 5⇡ ◆ 4
c cosec
cos
⇣ 5⇡ ⌘
4 ⇣ 5⇡ ⌘ sin 4 ⇣ ⇡⌘ cos ⇡ + 4 = ⇣ ⇡⌘ sin ⇡ + 4 ✓ 1 1◆ = p ÷ p 2 2 =1 =
✓ 7⇡ ◆ 4
c cosec =
✓ 7⇡ ◆ 4
1 ⇣ sin 2⇡
⇡⌘ 4
1 ⇣⇡⌘ sin 4 ✓ 1 ◆ =1÷ p 2 p = 2 =
Example 6 Find the values of x between 0 and 2⇡ for which: a sec x = 2
b cot x = 1
Solution a
sec x = 2 1 = 2 cos x 1 cos x = 2
b cot x = 1 tan x = 1 )
x=⇡
)
x=
Check that your calculator is in radian mode. Use
menu
)
x=⇡
)
x=
2⇡ 3
⇡ 3
or
x=⇡+
or
x=
4⇡ 3
⇡ 3
⇡ 4
3⇡ 4
or
x = 2⇡
or
x=
⇡ 4
7⇡ 4
Using the TI-Nspire Note: Access sec and cot using
a
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
. Access using
> Algebra > Solve as shown.
ctrl =
.
b
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14C Reciprocal functions and the Pythagorean identity 435
Using the Casio ClassPad The ClassPad does not recognise sec x, cosec x and cot x. These functions must be entered as reciprocals of cos x, sin x and tan x respectively. 1 a ⌅ Enter and highlight: = 2 0 x 2⇡ cos(x) ⌅ Select Interactive > Equation/Inequality > solve, ensure the variable is set to x and tap OK . 1 b ⌅ Enter and highlight: = 1 0 x 2⇡ tan(x) ⌅ Select Interactive > Equation/Inequality > solve, ensure the variable is set to x and tap OK . Note: The ‘for’ operator | is found in the
Math3
keyboard and is used to specify a condition. In this case, the condition is the domain restriction.
I The Pythagorean identity
y
Consider a point, P(✓), on the unit circle.
1
By Pythagoras’ theorem:
sin θ
OP2 = OM 2 + MP2 2
1 = (cos ✓) + (sin ✓)
)
P(θ)
-1
2
Since this is true for all values of ✓, it is called an identity. We can write (cos ✓)2 and (sin ✓)2 as cos2 ✓ and sin2 ✓, and therefore we obtain:
O cos θ M 1
x
-1
Pythagorean identity
cos2 ✓ + sin2 ✓ = 1 We can derive other forms of this identity: ⌅ Dividing both sides by cos2 ✓ gives
⌅ Dividing both sides by sin2 ✓ gives
cos2 ✓ sin2 ✓ 1 + = cos2 ✓ cos2 ✓ cos2 ✓ )
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1 + tan2 ✓ = sec2 ✓
cos2 ✓ sin2 ✓ 1 + = 2 2 sin ✓ sin ✓ sin2 ✓ )
cot2 ✓ + 1 = cosec2 ✓
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436 Chapter 14: Further trigonometry Example 7 a If cosec x =
7 , find cos x. 4
Solution a Since cosec x = Now
b If sec x =
7 4 , we have sin x = . 4 7
cos2 x + sin2 x = 1 16 cos2 x + =1 49 33 cos2 x = 49 p cos x = ±
)
33 7
3 ⇡ and x ⇡, find sin x. 2 2 3 , we have cos x = 2
b Since sec x = Now
2 . 3
cos2 x + sin2 x = 1 4 + sin2 x = 1 9 p )
sin x = ±
5 3
But sin x is positive for P(x) in p the 5 2nd quadrant, and so sin x = . 3
Example 8 If sin ✓ =
3 ⇡ and < ✓ < ⇡, find the values of cos ✓ and tan ✓. 5 2
Solution
)
cos2 ✓ + sin2 ✓ = 1 9 cos2 ✓ + =1 25 16 cos2 ✓ = 25 4 ⇡ sin ✓ , since < ✓ < ⇡, and therefore tan ✓ = = 5 2 cos ✓
Thus cos ✓ =
3 . 4
Example 9 Prove the identity Solution LHS = = = =
1
1
1 1 + = 2 cosec2 ✓. cos ✓ 1 + cos ✓
1 1 + cos ✓ 1 + cos ✓
1 + cos ✓ + 1 cos ✓ 1 cos2 ✓ 1
2 cos2 ✓
2 sin2 ✓
= 2 cosec2 ✓ = RHS Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
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14C Reciprocal functions and the Pythagorean identity 437
14C Section summary ⌅ Reciprocal functions
⌅ Pythagorean identity
1 cos ✓
(for cos ✓ , 0)
1 cosec ✓ = sin ✓
(for sin ✓ , 0)
cos ✓ sin ✓
(for sin ✓ , 0)
sec ✓ =
cot ✓ =
cos2 ✓ + sin2 ✓ = 1 1 + tan2 ✓ = sec2 ✓ cot2 ✓ + 1 = cosec2 ✓
Exercise 14C Example 5
1
2
Find the exact value of each of the following: ✓ 3⇡ ◆ ✓ 5⇡ ◆ ✓ 5⇡ ◆ a cot b cosec c sec 4 4 6 ✓ 4⇡ ◆ ✓ 13⇡ ◆ ✓ 7⇡ ◆ e sec f cosec g cot 3 6 3
Example 7, 8
3
4
b sec 150 g cot 315
c cosec 90 h cosec 300
d cot 240 i cot 420
Find the values of x between 0 and 2⇡ for which: p p a cosec x = 2 b cot x = 3 c sec x + 2 = 0 If sec ✓ = a cos ✓
Example 9
h sec
✓⇡◆
2 ✓ 5⇡ ◆ 3
Without using a calculator, write down the exact value of each of the following: a cot 135 f sec 330
Example 6
d cosec
17 ⇡ and < ✓ < ⇡, find: 8 2 b sin ✓
e cosec 225
d cosec x = sec x
c tan ✓
7 3⇡ and < ✓ < 2⇡, find cos ✓ and sin ✓. 24 2
5
If tan ✓ =
6
Find the value of sec ✓ if tan ✓ = 0.4 and ✓ is not in the 1st quadrant.
7
If tan ✓ =
4 3⇡ sin ✓ 2 cos ✓ and ⇡ < ✓ < , evaluate . 3 2 cot ✓ sin ✓
8
If cos ✓ =
2 tan ✓ and ✓ is in the 4th quadrant, express 3 cos ✓
9
Prove each of the following identities for suitable values of ✓ and ': a (1
cos2 ✓)(1 + cot2 ✓) = 1
3 sin ✓ in simplest surd form. 2 cot ✓
b cos2 ✓ tan2 ✓ + sin2 ✓ cot2 ✓ = 1
c
tan ✓ tan ✓ + cot ' = tan ' cot ✓ + tan '
d (sin ✓ + cos ✓)2 + (sin ✓
e
1 + cot2 ✓ = sec ✓ cot ✓ cosec ✓
f sec ✓ + tan ✓ =
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
cos ✓)2 = 2
cos ✓ 1 sin ✓
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438 Chapter 14: Further trigonometry
14D Addition formulas and double angle formulas I Addition formulas Addition formulas for cosine
1 cos(u + v) = cos u cos v sin u sin v 2 cos(u v) = cos u cos v + sin u sin v Proof Consider a unit circle as shown:
y
arc length AB = v units
u-v
arc length AC = u units arc length BC = u
v), sin(u
(cos v, sin v)
C
v units
Rotate OCB so that B is coincident with A. Then C is moved to P cos(u
1
(cos u, sin u)
B A 1
O
-1
v)
y
Since the triangles CBO and PAO are congruent, we have CB = PA.
(cos(u − v), sin(u − v)) 1
P
Using the coordinate distance formula: cos v 2 + sin u
CB2 = cos u =2
sin v
=2
v)
2 cos(u
1 2 + sin(u
v)
u−v
2
2 cos u cos v + sin u sin v
PA2 = cos(u
x
O
-1
0
A (1, 0)
x
2
v)
Since CB = PA, this gives 2 )
2 cos(u cos(u
v) = 2
2 cos u cos v + sin u sin v
v) = cos u cos v + sin u sin v
We can now obtain the first formula from the second by replacing v with v: cos(u + v) = cos(u
( v))
= cos u cos( v) + sin u sin( v) = cos u cos v
sin u sin v
Note: Here we used cos( ✓) = cos ✓ and sin( ✓) =
sin ✓.
Using the TI-Nspire Access the tExpand( ) command from menu > Algebra > Trigonometry > Expand and complete as shown.
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14D Addition formulas and double angle formulas 439
Using the Casio ClassPad ⌅ In M, enter and highlight cos(x y). ⌅ Go to Interactive > Transformation > tExpand
and tap
OK .
Example 10 Evaluate cos 75 . Solution cos 75 = cos(45 + 30 ) = cos 45 cos 30 sin 45 sin 30 p 1 3 1 1 = p · p · 2 2 2 2 p 3 1 = p 2 2 p p 3 1 2 = p ·p 2 2 2 p p 6 2 = 4 Addition formulas for sine
1 sin(u + v) = sin u cos v + cos u sin v 2 sin(u v) = sin u cos v cos u sin v ✓⇡ ◆ ✓⇡ Proof We use the symmetry properties sin ✓ = cos ✓ and cos ✓ = sin 2 2 ✓⇡ ◆ sin(u + v) = cos (u + v) 2 ✓⇣ ⇡ ◆ ⌘ = cos u v 2 ✓⇡ ◆ ✓⇡ ◆ = cos u cos v + sin u sin v 2 2 = sin u cos v + cos u sin v
◆ ✓:
We can now obtain the second formula from the first by replacing v with v: sin(u
v) = sin u cos( v) + cos u sin( v) = sin u cos v
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
cos u sin v
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440 Chapter 14: Further trigonometry Example 11 Evaluate: a sin 75
b sin 15
Solution a sin 75 = sin(30 + 45 )
b sin 15 = sin(45
= sin 30 cos 45 + cos 30 sin 45 p 1 1 3 1 = ·p + ·p 2 2 2 2 p 1+ 3 = p 2 2 p p 1+ 3 2 = p ·p 2 2 2 p p 2+ 6 = 4
30 )
= sin 45 cos 30 p 1 3 1 = p · p 2 2 2 p 3 1 = p 2 2 p p 3 1 2 = p ·p 2 2 2 p p 6 2 = 4
cos 45 sin 30 ·
1 2
Addition formulas for tangent
1 tan(u + v) =
tan u + tan v 1 tan u tan v
2 tan(u
v) =
tan u tan v 1 + tan u tan v
Proof To obtain the first formula, we write tan(u + v) =
sin(u + v) sin u cos v + cos u sin v = cos(u + v) cos u cos v sin u sin v
Now divide the numerator and denominator by cos u cos v. The second formula can be obtained from the first by using tan( ✓) = tan ✓.
Example 12 If u and v are acute angles such that tan u = 4 and tan v = Solution tan(u
v) = = =
3 , show that u 5
v=
⇡ . 4
tan u tan v 1 + tan u tan v 4
3 5
1+4⇥
3 5
20 3 5+4⇥3
=1 )
u
v=
⇡ 4
Note: The function tan ✓ is one-to-one for 0 < ✓
0 }, positive real numbers
Regular polygon [p. 272] a polygon in which all the angles are equal and all the sides are equal
R \ {0} [p. 47] the set of real numbers excluding 0
Resultant force [p. 667] the vector sum of the forces acting at a point
R [p. 47] { x : x < 0 }, negative real numbers
R2 [p. 44] { (x, y) : x, y 2 R }; i.e. R2 is the set of all ordered pairs of real numbers
Radian One radian (written 1c ) is the angle subtended at the centre of the unit circle by an arc of length 1 unit: 180 ⇡c 1c = and 1 = ⇡ 180 Random sample [p. 348] a sample chosen using a random process so that each member of the population has an equal chance of being included Random variable [p. 353] a variable that takes its value from the outcome of a random experiment; e.g. the number of heads observed when a coin is tossed three times Rate [p. 157] describes how a certain quantity changes with respect to the change in another quantity (often time) Rational function [p. 162] a function of the form g(x) f (x) = , where g(x) and h(x) are polynomials h(x) Rational number [p. 43] a number that can be p written as , for some integers p and q with q , 0 q Real part of a complex number [p. 500] If z = a + bi, then Re(z) = a. Reciprocal circular functions [pp. 433, 456] the cosecant, secant and cotangent functions Reciprocal function [p. 454] The reciprocal of 1 the function y = f (x) is defined by y = . f (x) Recurrence relation [p. 111] a rule which enables each subsequent term of a sequence to be found from previous terms; e.g. t1 = 1, tn = tn 1 + 2 Reflection [p. 565] A reflection in a line ` maps each point in the plane to its mirror image on the other side of the line. ⌅ Reflection in the x-axis: (x, y) ! (x, y) ⌅ Reflection in the y-axis: (x, y) ! ( x, y) ⌅ Reflection in the line y = x: (x, y) ! (y, x) ⌅ Reflection in the line y = x: (x, y) ! ( y, x)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Rhombus [p. 278] a parallelogram with all sides of equal length Rotation matrix [p. 571] A rotation about the origin by ✓ degrees anticlockwise is expressed using matrix multiplication as " 0# " #" # x cos ✓ sin ✓ x = y0 sin ✓ cos ✓ y
S Sample [p. 348] a subset of the population which we select in order to make inferences about the whole population Sample mean, x [p. 351] the mean of all values of a measure in a particular sample. The values x¯ ¯ are the values of a random variable X. Sample proportion, p ˆ [p. 351] the proportion of individuals in a particular sample possessing a particular attribute. The values pˆ are the values of ˆ a random variable P. Sample statistic [p. 352] a statistical measure that is based on a sample from the population; the value varies from sample to sample Sampling distribution [p. 356] the distribution of a statistic which is calculated from a sample Sampling with replacement [p. 361] selecting individual objects sequentially from a group of objects, and replacing the selected object, so the probability of obtaining a particular object does not change with each successive selection Sampling without replacement [p. 361] selecting individual objects sequentially from a group of objects, and not replacing the selected object, so the probability of obtaining a particular object changes with each successive selection Scalar [p. 601] a real number; name used when working with vectors or matrices Scalar product [p. 611] The scalar product of two vectors a = a1 i + a2 j and b = b1 i + b2 j is given by a · b = a1 b1 + a2 b2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Glossary 695 Sets of numbers [pp. 43, 499] N is the set of natural numbers Z is the set of integers Q is the set of rational numbers R is the set of real numbers C is the set of complex numbers
Scientific notation [p. 5] see standard form 1 Secant function [pp. 433, 456] sec ✓ = cos ✓ for cos ✓ , 0
Sector [p. 404] Two radii and an arc define a region called a sector. In this diagram, the shaded region is a minor sector and the unshaded region is a major sector. A 1 Area of sector = r2 ✓ 2 where ✓c = \AOB O θ C D B
A r O
θ B
Selection [p. 207] see combination Sequence [p. 110] a list of numbers, with the order being important; e.g. 1, 1, 2, 3, 5, 8, 13, . . . The numbers of a sequence are called its terms, and the nth term is often denoted by tn . Series [p. 122] the sum of the terms in a sequence Set notation [p. 40] 2 means ‘is an element of’ < means ‘is not an element of’ ✓ means ‘is a subset of’ \ means ‘intersection’ [ means ‘union’ ? is the empty set, containing no elements ⇠ is the universal set, containing all elements being considered A0 is the complement of a set A |A| is the number of elements in a finite set A
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Signs of circular functions 1st quadrant 2nd quadrant 3rd quadrant 4th quadrant
all are positive sin is positive tan is positive cos is positive
y
S
A
T
C
x
Segment [pp. 317, 406] Every chord divides the interior of a circle into two regions called segments; the smaller is the minor segment (shaded), and the larger is the major segment. Area of segment 1 = r2 ✓ sin ✓ 2 where ✓c = \AOB
S
Secant of a circle [p. 317] a line that cuts a circle at two distinct points
Shear [p. 565] A shear moves each point in the plane by an amount proportional to its distance from an axis. ⌅ Shear parallel to the x-axis: (x, y) ! (x + cy, y) ⌅ Shear parallel to the y-axis: (x, y) ! (x, cx + y)
Glossary
Scalar product, properties [p. 612] ⌅ a · b = b · a ⌅ k(a · b) = (ka) · b = a · (kb) ⌅ a·0=0 ⌅ a · (b + c) = a · b + a · c ⌅ a · a = |a|2
Similar figures [p. 288] Two figures are similar if we can enlarge one figure so that its enlargement is congruent to the other figure. Similarity tests [p. 289] Two triangles are similar if one of the following conditions holds: ⌅ AAA two angles of one triangle are equal to two angles of the other triangle ⌅ SAS the ratios of two pairs of matching sides are equal and the included angles are equal ⌅ SSS the ratios of matching sides are equal ⌅ RHS the ratio of the hypotenuses of two right-angled triangles equals the ratio of another pair of sides. p Simplest form [p. 52] a surd a is in simplest form if the number under the square root has no factors which are squares of a rational number Simulation [p. 366] using technology (calculators or computers) to repeat a random process many times; e.g. random sampling Simultaneous equations [pp. 8, 169] equations of two or more lines or curves in the Cartesian plane, the solutions of which are the points of intersection of the lines or curves
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Glossary
T
696 Glossary Sine function [p. 388] sine ✓ is defined as the y-coordinate of the point P on the unit circle where OP forms an angle of ✓ radians with the positive direction of the x-axis. y 1
P(θ) = (cos θ, sin θ)
–1
O
cos θ
x
1
–1
y
p Surd of order n [p. 51] a number of the form n a, where a is a rational number which is not a perfect nth power p Surd, quadratic [p. 51] a number of the form a, where a is a rational number which is not the square of another rational number
y = sin θ
π –1
2π
θ
T
amplitude = 1 period = 2π
sin ✓ Tangent function [p. 430] tan ✓ = cos ✓ for cos ✓ , 0
Sine rule [p. 393] For triangle ABC: a b c = = B sin A sin B sin C c A
Tangent to a circle [p. 322] a line that touches the circle at exactly one point, called the point of contact
a b
C
The sine rule is used to find unknown quantities in a triangle given one side and two angles, or given two sides and a non-included angle. Speed [p. 642] the magnitude of velocity Speed, average [p. 642] total distance travelled average speed = total time taken Spread a measure of how spread out the data values are; a measure of the variability of the data Standard deviation a measure of the spread or variability of the distribution of numerical data about the mean, denoted s and defined by v t n 1 X (xi x¯)2 s= n 1 i=1 Standard form [p. 5] A number is in standard form when written as a product of a number between 1 and 10 and an integer power of 10; e.g. 6.626 ⇥ 10 34 . Also called scientific notation
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Subtraction of vectors [p. 601] If a = a1 i + a2 j + a3 k and b = b1 i + b2 j + b3 k, then a b = (a1 b1 )i + (a2 b2 ) j + (a3 b3 )k.
Supplementary angles [p. 266] two angles whose sum is 180
Sine function, graph
1
Subtraction of complex numbers [p. 501] If z1 = a + bi and z2 = c + di, then z1 z2 = (a c) + (b d)i.
Sum to infinity [p. 137] The sum to infinity of an infinite geometric series exists provided 1 < r < 1 and is given by a S1 = 1 r where a = t1 and r is the common ratio.
sin θ
θ
Statistic any value computed from a set of data
Transformation [p. 561] A transformation of the plane maps each point (x, y) in the plane to a new point (x0 , y0 ). We say that (x0 , y0 ) is the image of (x, y). Translation [p. 569] a transformation that moves each point in the plane in the same direction and over the same distance: (x, y) ! (x + a, y + b) Trapezium [p. 278] a quadrilateral with at least one pair of opposite sides parallel
Triangle inequality [p. 273] If a, b and c are the side lengths of a triangle, then a < b + c, b < c + a and c < a + b. Trigonometric ratios [p. 388] opposite sin ✓ = hypotenuse cos ✓ =
adjacent hypotenuse
opposite tan ✓ = adjacent
hypotenuse
opposite side
θ adjacent side
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Glossary 697
Union of sets [p. 40] The union of two sets A and B, written A [ B, is the set of all elements which are in A or B or both.
V Variance a measure of the spread or variability of the distribution of numerical data about the mean, denoted s2 and defined by n 1 X (xi x¯)2 s2 = n 1 i=1 Vector [p. 599] a set of equivalent directed line segments Vector quantity [p. 599] a quantity determined by its magnitude and direction; e.g. position, displacement, velocity, acceleration, force Vectors, parallel [p. 602] Two non-zero vectors a and b are parallel if and only if a = kb for some k 2 R \ {0}. Vectors, perpendicular [p. 612] Two non-zero vectors a and b are perpendicular if and only if a · b = 0.
Vectors, properties [pp. 599–601] ⌅ a+b= b+a commutative law ⌅ (a + b) + c = a + (b + c) associative law ⌅ a+0= a zero vector ⌅ a + ( a) = 0 additive inverse ⌅ m(a + b) = ma + mb distributive law
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Velocity [p. 642] The velocity of a particle is defined as the rate of change of its position with respect to time. Velocity, average [p. 642] change in position average velocity = change in time Velocity, instantaneous [p. 642] v =
U ! Z
Unit vector [p. 608] a vector of magnitude 1. The unit vectors in the positive directions of the x-, y- and z-axes are i, j and k respectively. The unit vector in the direction of a is given by 1 aˆ = a |a|
Vectors, resolution [p. 614] a vector a is resolved into rectangular components by writing it as a sum of two vectors, one parallel to a given vector b and the other perpendicular to b. The vector resolute of a in the direction of b is given by a·b u= b b·b
Glossary
U
dx dt
Velocity–time graph [p. 653] ⌅ Acceleration is given by the gradient. ⌅ Distance travelled is given by the sum of the areas of the regions between the graph and the t-axis. ⌅ Displacement is given by the sum of the signed areas of the regions between the graph and the t-axis.
W Weight [p. 667] On the Earth’s surface, a mass of m kg has a force of m kg wt (or mg newtons) acting on it; this force is known as the weight.
Z Zero vector, 0 [p. 601] a line segment of zero length with no direction
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
1A ! 1C
Answers
Answers
Chapter 1
Exercise 1B
Exercise 1A 1 a x7
b a2
12
c x3 7
dy
1 6 12
h a 8 l x2
e x i y14
f p j x15
g a ka
m n2 1 q 2n6
n 8x 2
oa
p x4
s a 2 b5
t 1
2 a 5 6 e 7 i 27
7
r
8x2
5 22n 4 6 63x ✓1◆1 6 7 a 2 19 6 1 3 a b ✓b◆1 2
d2
8 a d
g a
a
7 4 2 5 b c
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1 4 h 16
c
f3 3 j 2 3 a 18.92 b d 125 000 e g 0.14 h 4 a a4 b7 b d a6 b9
4 3 g 12
b4
d
k1 79.63 0.9 1.84 64a4 b7
e 2a4 b7
11
l8 c f i c
5.89 1.23 0.4 b a2 b5 f 128
5
b a 20
c 26
3
e 25 5
1
b a2 b2 e
5 1 a2 b2 c 4
4
1
c ab 5 f
1 3 a5 b5
1 a c e g i k 2 a c e 3 a c 4 a c e
4.78 ⇥ 10 b 7.923 ⇥ 10 d 2.3 ⇥ 10 3 f 1.200 034 ⇥ 10 h 2.3 ⇥ 1010 j 1.65 ⇥ 105 l 1.0 ⇥ 10 8 b 5 ⇥ 10 5 d 9.461 ⇥ 1012 f 81 280 000 000 000 b 0.000 000 000 000 28 4.569 ⇥ 102 b 5.6791 ⇥ 103 d 9.0 ⇥ 10 2 f
6.728 ⇥ 103 4.358 ⇥ 104 5.6 ⇥ 10 7 5.0 ⇥ 107 1.3 ⇥ 10 9 1.4567 ⇥ 10 5 1.67 ⇥ 10 24 1.853 18 ⇥ 103 2.998 ⇥ 1010 270 000 000
3.5 ⇥ 104 4.5 ⇥ 10 2 4.5682 ⇥ 103 262 b 2625 b 4.76 ⇥ 107
5 a 0.000 0567 6 a 11.8
Exercise 1C 8 3 d x = 63
1 a x=
g x = 0.3 21 j x= 17 160 2 a x= 9 80 d x= 51 487 g x= 13
b x = 48 e x = 0.7 h x= 6
20 3 f x = 2.4 15 i x= 92
c x=
b x = 19.2
c x= 4
e x = 6.75
f x=
h x=
85 38
191 91
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Answers 699 16 ,y= 11 d x = 8, y = 2 f x = 1, y = 6 b x=
18 11
Exercise 1D
1 4 6 7 9
140.625 km 2 50 3 10 000 adults Men $220; boys $160 5 127 and 85 252 litres 40% and 448 litres 15% 120 and 100; 60 8 $370 588 500 adults, 1100 students
Exercise 1F 1 a 25 b 330 e 612.01 f 77.95 i 9.43 j 9.54 v u 2 a a= b `= rt P d I=± e a= R r 2E f v=± g h= m b(c + y) i x= a c
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
4 a 1080 5 a 115.45 cm3 6 a 66.5
c 340.47 d 1653.48 g 2.42 h 2.1 2S n 2(s
2A a c b= h ut) t2
Q2 2g
z h x= y b(c + 1) j x= m c
5(F
32) 9
; 57.22 C
S b n= + 2; 9 sides 180 b 12.53 cm c 5.00 cm b 4 c 11
Exercise 1G 1 a e g i k m o q
13x 5a h 5x 2y b c d 6 4 8 12 3y + 2x 7x 2 f xy x(x 1) 5x 1 7x2 36x + 27 h (x 2)(x + 1) 2(x + 3)(x 3) 4x + 7 5a2 + 8a 16 j (x + 1)2 8a 4(x2 + 1) 2x + 5 l 5x (x + 4)2 3x + 14 x + 14 n (x 1)(x + 4) (x 2)(x + 2) 7x2 + 28x + 16 (x y)2 1 p (x 2)(x + 2)(x + 3) x y 4x + 3 3 2x r x 1 x 2 xy 2 x c d 2 8 x y a 1 x 1 f g h x+2 3 2x x+4 x 1 a 2x x 1 j k l x 4b x+2 4x x+1 1 n x(x + 3) 2x 3 x 2 3x(3x 2)(x + 5) 3 4x 14 b 2 x 3 x 7x + 12 5x 1 2x2 + 10x 6 d 2 x + x 12 x2 + x 12 2x 9 5x 8 f x2 10x + 25 (x 4)2 1 23 3x h 2 3 x x + x 12 5x2 3x 11 2x j 2 2 x 9 x 10x + 25 12 9x 25 l 2 3 (x 6) x 7x + 12 p 3 x 2 x 4+6 5 b c p p p 1 x 3 x 4 x+4 x+7 12x2 9x2 (x + 2) e p f p p 2 x+3 x+4 x+4 6x 4 3 3 3x b c 2 2 2 (6x 3) 3 (2x + 3) 3 (x 3) 3
2 a 2xy2 e i m o
Exercise 1E
bC=
3 a c e g i k 4 a d 5 a
1D ! 1G
1 a 4(x 2) = 60; x = 17 ✓ 2x + 7 ◆2 b = 49; x = 10.5 4 29 c x 5 = 2(12 x); x = d y = 6x 4 3 e Q = np f R = 1.1pS 60n ⇡ g = 2400 h a = (x + 3) 5 3 2 $2500 3 Eight dresses and three handbags 4 8.375 m by 25.125 m 5 $56.50 6 Nine 7 20, 34 and 17 8 Annie 165, Belinda 150, Cassie 189 9 15 km/h 10 2.04 ⇥ 10 23 g 11 30 pearls 12 Oldest $48, Middle $36, Youngest $12 13 98% 14 25 students 15 After 20 minutes 16 a 40 minutes b 90 minutes c 20 minutes 17 200 km 18 39 km/h
3 a 82.4 F
Answers
18 14 ,y= 13 13 c x = 12, y = 17 e x = 0, y = 2
3 a x=
b
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Answers
1H ! 1 review
700 Answers Exercise 1H 1 a x= d x=
m
n a 5
p
g x = 3a
q
b b a m+n e x= n m
b x=
h x = mn
p q 3ab k x= p+q b a p 2 + p2 t + t 2 m x= q(p + t) j x=
c x= f x=
bc a ab
1 b a2 b2 i x= 2ab 1 l x= 3a b 5a n x= 3
d bc c ad ,y= 1 ab 1 ab a2 + ab + b2 ab x= ,y= a+b a+b t+s t s x= ,y= d x = a + b, y = a 2a 2b x = c, y = a f x = a + 1, y = a 2a2 s = a(2a + 1) b s= 1 a a2 + a + 1 a s= d s= a(a + 1) (a 1)2 3a s = 3a3 (3a + 1) f s= a+2 1 5a2 s = 2a2 1 + 2 h s= 2 a a +6
5 6 7 8 9
10
4 a x= b c e 5 a c e g
Exercise 1I 1 a x=a c x= 2 a b c d
(x (x (a2 (a
3 a x= b x=
b b x=7 p a ± a2 + 4ab 4b2 a+c d x= 2 2 1)(x + 1)(y 1)(y + 1) 1)(x + 1)(x + 2) 12b)(a2 + 4b) c)(a 2b + c) a+b+c a+b ,y= a+b c (a b c) a b+c ,y= a+b c a+b c
Chapter 1 review Technology-free questions 1 a x12 by 9 2 3.84 ⇥ 108 2x + y 3 a 10 7x 1 c (x + 2)(x 1) 13x2 + 2x + 40 e 2(x + 4)(x 2) 2 x 4 4 a b x 4x Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
c
15x
d x
1
7x xy 7x + 20 d (x + 2)(x + 4) 3(x 4) f (x 2)2 x2 4 c d 4x2 3 b
4y
11 2
11
b 1
12 13 14 15 16
106 seconds or 11 31 days 54 50 12 88 classical, 80 blues, 252 heavy metal V 117 a 300⇡ cm3 b h = 2; cm ⇡r 5⇡ r r p V 128 8 2 c r= ; cm = p cm ⇡h ⇡ ⇡ b a+b a x= b x= a+y c 2ab ab + b2 d d2 c x= d x= b a d(a + b) p2 + q2 x+y a 2 b p q2 x(y x) 2 c (x 2)(2x 1) d a A 36; B 12; C 2 a a = 8, b = 18 b x = p + q, y = 2q x = 3.5 40cx2 a 4n2 k2 b ab2 x= 1
Multiple-choice questions 1 A 2 A 3C 6 E 7 B 8B
4 A 9 B
5B 10 B
Extended-response questions 5x 4x 19x 1 a hours b hours c hours 4 7 28 14 d i x= ⇡ 0.737 19 140 560 ii Jack ⇡ 7 km; Benny ⇡ 29 km 19 19 3 2 a 18 000 cm per minute 45t b V = 18 000t c h = d After 4⇡ 3a 3 a Thomas a; George ; Sally a 18; 2 a 5a Zeb ; Henry 3 6 3a a 5a b + a 18 + = a + +6 2 3 6 c a = 24; Thomas 24; Henry 20; George 36; Sally 6; Zeb 8 Fr2 1011 4 a 1.9 ⇥ 10 8 N b m1 = 6.67m2 c 9.8 ⇥ 1024 kg 5 a V = (1.8 ⇥ 107 )d b 5.4 ⇥ 108 m3 3 c k = 9.81 ⇥ 10 d 1.325 ⇥ 1015 J e 1202 days (to the nearest day) p 10 3 6 cm 3 7 40 240 8 km/h 11
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Answers 701
10 a b c
Chapter 2
5
x
p r
X
6
s
w
q
t
u
Y
v
a {p, q, u, v} b {p, r, w} c {p} d {p, q, r, u, v, w} e {q, r, s, t, u, v, w} f {p}
x
5 7 9
a c d e 7 a
2 6
1 3
X
11 4 12
8 10
{5, 7, 8, 9, 10, 11} {1, 3, 5, 7, 8, 9, 10, 11} {1, 3, 5, 7, 8, 9, 10, 11} {1, 2, 3, 4, 6, 8, 10, 12} ξ
2A
11 a c
r3 ◆ ⇡ 3 ii r = 5.94 cm; h = 14.06 cm 2 1 litre from A; litre from B 3 3 600 mL from A; 400 mL from B (p q)(n + m) litres from A, 2(np qm) (n m)(p + q) litres from B, 2(np qm) n q n q where , and one of or is 1 m p m p and the other is 1 h = 2(10 r) b V = 2⇡r2 (10 r) r = 3.4985, h = 13 or r = 9.022, h = 1.955
Answers
9 a h = 20 ✓ r b i V = 20r2
Y
b {1, 3, 5, 7, 9, 11} f {5, 7, 9, 11}
A
B
A
B
A¢
Exercise 2A 1
x
b
3 1
A
2
1 P 9
3
ξ
7
11
3
6
2
15
12
c
10
A
4 12
d
A
e
3 5 7 9
16 P
a b c d e
A
B
f
ξ A
B
(A È B)¢
10 15 25
Q
{10, 11, 13, 14, 15, 17, 18, 19, 21, 22, 23, 25} {11, 12, 13, 14, 16, 17, 18, 19, 21, 22, 23, 24} {10, 12, 15, 16, 20, 24, 25} {11, 13, 14, 17, 18, 19, 21, 22, 23} {11, 13, 14, 17, 18, 19, 21, 22, 23}
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
ξ
11
20 24
B
AÈB
11 13 14 17 18 19 21 22 23 12
ξ A¢ È B¢
a {1, 2, 3, 5, 6, 7, 9, 10, 11} b {1, 3, 5, 7, 9, 11} c {2, 4, 6, 8, 10, 12} d {1, 3, 5, 7, 9, 11} e {1, 3, 5, 7, 9, 11}
x
B
Q
8 10 14 16
8
A
A¢ Ç B¢
4
1 2 6
ξ
13
{1, 2, 4, 5, 7, 8, 10, 11, 13, 14, 16} {1, 3, 5, 7, 9, 11, 13, 15} {2, 3, 4, 6, 8, 9, 10, 12, 14, 15, 16} {1, 5, 7, 11, 13} e {1, 5, 7, 11, 13} B
4
5
ξ B¢
b {1, 3, 5} c {1, 2, 3, 4, 5} = ⇠ e?
x
a b c d
B
5
a {4} d? 2
4
8
x
A G
B
R L E A N
a {R} b {G, R} c {L, E, A, N} d {A, N, G, E, L} e {R} f {G, R}
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Answers
2B ! 2D
702 Answers 9
ξ
f [ 3, 1]
M H I
A
S
C
T
E
A
−5 −4 −3 −2 −1
B
4 a
0
1
2
3
4
5
−3 −2 −1
0
1
2
3
4
−3 −2 −1
0
1
2
3
4
−2 −1
0
1
2
3
4
5
−2 −1
0
1
2
3
4
5
(4, 1)
b (–3, 2)
–1 –1
–5
c
d
2 a 3, 1 e
1, 7
1 2 4
2 e 2 f4 12 6 c , d 12, 6 5 5 2 g , 4 5
3 a ( 3, 3) −5 −4 −3 −2 −1
0
2
1
3
4
5
0
1
0
1
2
3
4
5
6
c [1, 3] −5 −4 −3 −2 −1
2
3
4
5
d ( 1, 5) −5 −4 −3 −2 −1
0
1
2
3
4
5
e ( 1, 8] [ [2, 1) −9 −8 −7 −6 −5 −4 −3 −2 −1
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Range ( 1, 2]
y
–1
0
1
2
3
3
x
5 a b c e f 6 a
{x : 5 x 5} { x : x 2} [ { x : x 2} {x : 1 x 2} d {x: { x : x 4 } [ { x : x 10 } {x : 1 x 3} x 2 b x = 9 or x = 11 5 15 c x= or x = 4 4 7 a = 1, b = 1
Exercise 2D
b ( 1, 5] [ [5, 1) −6 −5 −4 −3 −2 −1
x
1
c ( 1, 3] f [ 2, 3]
d
2
Range [ 1, 1)
(1, 2)
Exercise 2C c 7 b , 2 4 f , 3
x
y
–5 –3 (–4, –1)
e
b8
Range ( 1, 2]
3
d
1 a 8
5
3
c
b [ 3, 1) e [ 2, 3) h ( 5, 3)
4
x
y
b
6 a ( 1, 3) d (5, 1) g ( 2, 3]
3
Range [1, 1)
O
b Yes c Yes b No c No 3 2 4 2 c d e f 25 7 11 9 b 0.4˙ 5˙ c 0.35 ˙ e 0.058823529411764 7˙
2
5
Exercise 2B 1 a Yes 2 a No 9 3 3 a b 20 11 ˙ 4 a 0.28571 4˙ ˙ d 0.30769 2˙ 5 a
1
y
a {E, H, M, S} b {C, H, I, M} c {A, T} d {H, M} e {C, E, H, I, M, S} f {H, M}
−2 −1
0
p p 1 a 2p2 b 2 p 3 c e 3 5 f 11 p 10 g i 5 j 5 3 k p p 2 a 3p2 b 6 p 3 d 5 10 e 28 2 p p 3 a 11 3 + 14 b c 0p d p e 5 2 + 15 3 f p p 5 7 4 a b 5p p7 2 3 6 d e 3 2
p 3p3 7 p 2 16 2
1 5
< x < 1}
p d 5p2 h 6 3 p c 4 7 f 0
p 5 p 7 p p2 + p3 2+ 5
p 2 c 2 p 2 f 4
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 703 p
2
j
p
6
p h 2+ 3 p p 5+ 3 k 2
1
p 4 + 10 6 p p l 3( 6 + 5) i
11 b
1
1
23
2
8 10 5 0
6 x = 17, y = 20; Solutions of 19x + 98y = 1998 with x, y 2 N are x = 100, y = 1 and x = 2, y = 20 7 (10, 0), (9, 5), (8, 10), (7, 15), (6, 20), (5, 25), (4, 30), (3, 35), (2, 40), (1, 45), (0, 50) 8 63x 23y = 7; x = 5 + 23t, y = 14 + 63t for t 2 N [ {0} 9 5 and 15 10 20; 20 + 77t for t 2 N [ {0} 11 Pour two full 5 litre jugs into a container and remove one 3 litre jugful 12 All amounts greater than or equal to 3c, except 4c and 7c 13 8 type A, 16 type B 14 The highest common factor of 6 and 9 is 3, which does not divide 10 15 221 16 52 and 97
2E ! 2H
2 p m 3+2 2 p p p 5 a 6+4 2 b 9p +4 5 c 1 + p2 p 2 3 8+5 3 d4 2 3 e f 9 11 p p 3+ 5 6+5 2 g h 2 p 14 6 a 4a 4 a +p1 b 3 + 2x + 2 (x + 1)(x + 2) p p 7 a 5 3 2 b 7 2 6 p p 3 5 5 8 8 a p b c d p 2 5 3 2 9 a b = 0, c = 3 b b = 0, c = 12 c b = 2, c = 1 d b = 4, c = 1 e b = 6, c =p1 p f b = 7 + 5 5, c = 58 13 5 p p p 3 2+2 3 30 10 12
5 50c 0 2 4 6 20c 25 20 15 10
Answers
g
Exercise 2G
23
Exercise 2E 1 a 22 ⇥ 3 ⇥ 5 b 22 ⇥ 132 2 c 2 ⇥ 3 ⇥ 19 d 22 ⇥ 32 ⇥ 52 e 22 ⇥ 32 ⇥ 7 f 22 ⇥ 32 ⇥ 52 ⇥ 7 5 g 2 ⇥ 3 ⇥ 5 ⇥ 11 ⇥ 13 h 25 ⇥ 3 ⇥ 7 ⇥ 11 ⇥ 13 i 25 ⇥ 7 ⇥ 11 ⇥ 13 j 25 ⇥ 7 ⇥ 11 ⇥ 13 ⇥ 17 2 a 1 b 27 c 5 d 31 e 6 3 a 18: 1, 2, 3, 6, 9, 18; 36: 1, 2, 3, 4, 6, 9, 18, 36 b 36 is a square number (36 = 6 ⇥ 6) c 121 has factors 1, 11 and 121 4 5, 14 and 15 5 n = 121 6 105 7 8 84 9 1:12 p.m. 10 600 and 108 000; 2400 and 27 000; 3000 and 21 600; 5400 and 12 000;
1 a 43 = 8 ⇥ 5 + 3; HCF(43, 5) = HCF(5, 3) = 1 b 39 = 3 ⇥ 13 + 0; HCF(39, 13) = HCF(13, 0) = 13 c 37 = 2 ⇥ 17 + 3; HCF(37, 17) = HCF(17, 3) = 1 d 128 = 16 ⇥ 8 + 0; HCF(128, 16) = HCF(16, 0) = 16 3 a 1 b 27 c 6 d 5 4 a x = 44 + 393t, y = 15 134t, t 2 Z b x = 1 + 4t, y = 1 3t, t 2 Z c x = 2 + 4t, y = 118 3t, t 2 Z d x = 1 + 5t, y = 7 + 3t, t 2 Z e x = 107 + 224t, y = 32 67t, t 2 Z f x = 37 + 336t, y = 25 227t, t 2 Z
Exercise 2H 1 a
ξ H
E 9
5
14
Exercise 2F 1 a x = 2 + 3t, y = 7 11t, t 2 Z b x = 1 + 7t, y = 2t, t 2 Z c x = 12 + 21t, y = 3 8t, t 2 Z d x = 2 + 3t, y = 7 11t, t 2 Z e x = 11 + 7t, y = 2t, t 2 Z f x = 11 + 7t, y = 2t, t 2 Z 2 x = 4, y = 2 4 a 8s + 6b = 54 b s = 6, b = 1 or s = 3, b = 5
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b i 19 2 a ξ
ii 9
iii 23
A
14
3
5 6
C
b i 23 3 20%
B
ii 37
9
2 4 7
iii 9
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
4 5 6 7 8
7 a 5 45 a x=5 a ξ
Multiple-choice questions 1 A 2 D 3D 6 D 7 B 8B 11 D 12 D 13 A
b 10 b 16
X
Answers
2 review
704 Answers
22 35 31
c 0
23 34
26
21 24
28
36 25 1
Z
12
27
4 49
Y 6
15 18 39
33 30
29 32
3
9 16
b i X \ Y \ Z = {36} ii |X \ Y| = 5 9 31 students; 15 black, 12 green, 20 red 10 |M \ F| = 11 11 1 12 x = 6; 16 students 13 102 students
Chapter 2 review Technology-free questions 7 5 1 1 a b c 90 11 200 81 4 6 d e f 200 15 35 2 23 ⇥ 32 ⇥ 7 3 a n = ±2 or n = ±4 b i x = ±1 ii x 0 c xp < 1p or x > 1 p p 2 6 2 4 a b 4 5+9 c 2 6+5 2p 5 23 12 3 p p a a2 b2 6 a 2 6+6 b b 7 a 15 b 15 8 a 1 b 22 c 22 95 p 10 2 cm2 11 15 7 12 x = ±2 p p p 51 3 13 5 6 14 5 15 a 57 b3 c 32 p 16 2 2 + 3 17 HCF(1885, 365) = 5 18 a x = 4 + 43t, y = 1 9t, t 2 Z b No solutions for x, y 2 N 20 HCF(10 659, 12 121) = 17 21 a x = 3 + 7t, y = 2 5t, t 2 Z b x = 6 + 7t, y = 10 5t, t 2 Z c x = 3 + 7t, y = 2 5t, t 2 Z 22 Tom is 36 and Fred is 27
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
4 D 9 C
5C 10 A
Extended-response questions p p 1 c i p 11 + p3 p p ii 2p2 7 or 7p 2 2p p iii 3 3 2 6 or 2 6 3 3 2 a a = 6, b = 5 b p = 26, q = 16 2 c a = 1, b = 3 p p p 12 3 19 1± 3 di ii 3 ± 3 iii 71 p 2 e Q = {a + 0 3 : a 2 Q} 3 d x = ±2 p 5 a b = 4, c = 1 b 2+ 3 6 a (20, 21, 29) 7 a i 4 factors ii 8 factors b n + 1 factors c i 32 factors ii (n + 1)(m + 1) factors d (↵1 + 1)(↵2 + 1) · · · (↵n + 1) factors e 24 8 a 1080 = 23 ⇥ 33 ⇥ 5; 25 200 = 24 ⇥ 32 ⇥ 52 ⇥ 7 b 75 600 d i 3470, 3472, 3474, 3476 ii 1735, 1736, 1737, 1738 9 a i region 8 ii male, red hair, blue eyes iii male, not red hair, blue eyes b i 5 ii 182 10 a i students shorter than or equal to 180 cm ii students who are female or taller than 180 cm iii students who are male and shorter than or equal to 180 cm b A B
(A ∪ B)¢ = A¢ ∩ B¢ is shaded
11 a
A
B 65
35
205 80
35
80
C
|A ∩ C| = 0
b 160
c 65
d 0
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 705 c k=3
d k=
Chapter 3
x 1 2 3 y 3 4
1 3
1 8 2 y 3 x
Exercise 3A
1 b k= 3
c k=3 d k=
2 5
x 2 4 6 8 y 8 32 72 128 1 2 1 y 6 x
1 1 3
3 2 1 2
2 2 3
x 4 9 49 900 y 6 9 21 90 1 32 1 y 5 x
3 4 5 6 7 8
1 32 1024 2 5
4 5
8 5
2 a V = 262.144 b r ⇡ 2.924 3 a a ⇡ 1.058 b b ⇡ 5.196 2 4 a 72 cm b 20 cm 648 5 a cm b 1412.5 g 113 6 10.125 kg 7 62.035 cm 8 a 300% b 800% c 21% 9 52% 10 1.898 s 11 a 8.616 km b 14.221 km 12 a i 300% increase ii 41% increase iii 700% increase b i 75% decrease ii 29% decrease iii 87.5% decrease c i 36% decrease ii 11% decrease iii 48.8% decrease d i 96% increase ii 18% increase iii 174.4% increase
1 b b ⇡ 5.657 2 a a = 0.3125 b 2 2.85 kg/cm a 2.4 amperes b 64 candela 5.15 cm a i 75% decrease ii iii 87.5% decrease b i 300% increase ii iii 700% increase c i 56.25% increase ii iii 95% increase d i 49% decrease ii iii 64% decrease
2 a a=
b k=
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1 2
x 2 4 1 y 1 2
6 1 3
32 1 16
1 4
1
4
9
y 1
1 2
x
1 4
1 6
1 27 125 1 3
1 9
1 15
p b= 2 25%
29% decrease 41% increase 12% increase 15% decrease
Exercise 3C 1 a direct c inverse e inverse square 2 a y/p x2 (possibly) c y / x (possibly) 3 a, b, e 4 a y = 3x p d y=2 x 5
b y=
b direct square d direct square root b y/x 3 x
c y=
1 e y= p 3 x 6
y
8
30
6
20
4
f y = 6x3
2
10 0
7
10 2 x 3
y
40
Exercise 3B 1 a k=2
6 1 12
3A ! 3C
1 a k=2
3 1 3
Answers
12 a 6 ⇥ 5c + 1 ⇥ 8c b 15 ⇥ 8c, 8 ⇥ 5c + 10 ⇥ 8c, 16 ⇥ 5c + 5 ⇥ 8c, 24 ⇥ 5c
4 8 12 16 y = 2.4x2
x2
0
1 2 3 4 5 y = 1.5√x
√x
y 50 40 30 20 10 0
5 10 15 20 25 2 y= 2 x
1 x2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
3D ! 3 review
706 Answers 5 1p x b y = 2x 4 4 2 5 d y = 10x 3 e y = 2x 2 9 a a = 100, b = 0.2 10 a a = 1500, b = 0.5
8 a y=
c y = 3.5x0.4 f y = 3.2x b 158.49 b 474.34
0.4
Exercise 3D 1 k=5
2 k=
1 2
3 k=3
x 2 4 6 10 z 10 2 60 12.5 y 1 10 0.5 4 x 2 4 1 10 z 10 8 50 3 y 10 16 25 15 x
2
z 10 y 4 5 6 7 8 9 10 11 12
15 2
3
5
10 400 4 50 3 4 6 4 3
a ⇡ 1.449 z ⇡ 0.397 a 9.8 J/kg.m b 5880 J $174 360 J a 500% increase b 78% decrease a 41% increase b 33% increase a 183% increase b 466% increase a Tensions are the same b Work done by the second spring is 90% of the work done by the first
Exercise 3E 1 $33.40 2 a Overhead charge $1250; cost per guest $237.50 b $25 000 3 p = 20.5 4 $55.11 5 a 330 m b 67.5 m 6 45 minutes
Chapter 3 review Technology-free questions 8 1 a When b = 4, a = 6; when a = 8, b = ± p 3 30 b When x = 27, y = 1 ; 23 1 1 when y = , x = 8 256 000
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
2 3 4 5 6 7 8 9 10
1 16 4 c When x = , y = ; when y = , x = ±3 2 3 27 1 d a= 6 a d = 4.91t2 b 491 m c 2 s, correct to one decimal place p a 14 m/s b 40 m c v and s 2.4 hours a y is halved b x is halved c y is doubled d x is doubled 4.05 cents $35 18 amps 1 I2 = I1 4 34% increase
Multiple-choice questions 1 C 2 A 3 B 6 D 7 E 8 D
4 C 9 D
5B 10 B
Extended-response questions 1 a 0.24 kg b 11 cm 2 a h = 0.000 3375n2 b 17.1 m c 218 rpm 3 13 knots 121.8 4 a V= b 9.6 kg/cm2 P 3000 5 a w= b 600 kg c 333 kg d 144 6 a v= p b i v=2 ii p = 48 c y 12 9 8
0
1 1 1 18 16 12
1 p
7 44.8 minutes 8 $76 1 9 S n = n(n + 1) 2 10 a P = 3498.544 ⇥ N 0.5 b 25 956 c 51 023 3600 11 a t = 2 b T = 0.14d2 c 23.9 mL d d 6.3 min e 9 min; 56 min 12 a i T = 0.000 539 ⇥ R1.501 ii Mars 1.87; Jupiter 11.86; Saturn 29.45; Uranus 84.09; Neptune 165.05 b 2.540 ⇥ 109 km 13 a a = 11.7, b = 0.41 b 77 c k = 163, p = 1.167 d 7
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Answers 707
Exercise 4A
3
4
5 6 7 8
9
10
11
12
13 14 15
3, 7, 11, 15, 19 b 5, 19, 61, 187, 565 1, 5, 25, 125, 625 d 1, 1, 3, 5, 7 1, 3, 7, 17, 41 tn = tn 1 + 3, t1 = 3 b tn = 2tn 1 , t1 = 1 tn = 2tn 1 , t1 = 3 d tn = tn 1 + 3, t1 = 4 tn = tn 1 + 5, t1 = 4 1 1 1 a 1, , , b 2, 5, 10, 17 2 3 4 c 2, 4, 6, 8 d 2, 4, 8, 16 e 5, 8, 11, 14 f 1, 8, 27, 64 g 3, 5, 7, 9 h 2, 6, 18, 54 a tn = 3n b tn = 2n 1 1 c tn = 2 d tn = 3( 2)n 1 n e tn = 3n + 1 f tn = 5n 1 tn+1 = 3n + 4, t2n = 6n + 1 a t1 = 15, tn = tn 1 + 3 b tn = 12 + 3n c t13 = 51 a t1 = 94.3, tn = 0.96tn 1 b tn = 94.3(0.96)n 1 c t9 = 68.03 a t0 = 100, tn = 1.8tn 1 + 20 b t1 = 200, t2 = 380, t3 = 704, t4 = 1287, t5 = 2336 a 1st year $2120; 2nd year $2671.20; 3rd year $3255.47 b tn = 1.06(tn 1 + 400), t1 = 2120 c $8454.02 a 1, 4, 7, 10, 13, 16 b 3, 1, 1, 3, 5, 7 1 c , 1, 2, 4, 8, 16 d 32, 16, 8, 4, 2, 1 2 a 1.1, 1.21, 1.4641, 2.144, 4.595, 21.114 16 32 b 27, 18, 12, 8, , 3 9 c 1, 3, 11, 27, 59, 123 d 3, 7, 3, 7, 3, 7 a t1 = 1, t2 = 2, t3 = 4 b u1 = 1, u2 = 2, u3 = 4 c t1 = u1 , t2 = u2 , t3 = u3 d t4 = 8, u4 = 7 S 1 = a + b, S 2 = 4a + 2b, S 3 = 9a + 3b, S n+1 S n = 2an + a + b p 3 17 577 t2 = , t3 = , t4 = ; the number is 2 2 12 408 t3 = 2, t4 = 3, t5 = 5
Exercise 4C 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
Exercise 4B
20
1 a 0,p2, 4, 6p b p 3, 2, 7, p 12 c 5, 2 5, 3 5, 4 5 d 11, 9, 7, 5 p 2 a 31 b 24 c 5 d6 3
21 22 23
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
4A ! 4C
1 a c e 2 a c e
3 a a = 3, d = 4, tn = 4n 1 b a = 3, d = 4, tn = 7 4n 1 5 c a= , d = 2, tn = 2n 2p 2 p p p d a=5 5, d = 5, tn = 5n + 5 2 5 4 a 13 b 8 c 20 d 56 5 a = 5, d = 3, t7 = 13 6 tn = 156n 450 7 2p 8 54 9 27 3 60 10 a 672 b 91st week 11 a 70 b 94 c Row F 12 117 218 13 9 14 7, 9, 11, 13 a(n 1) 15 tn = a m 1p 2 2 16 a 11.5 b 7 17 16 18 5 20 3
Answers
Chapter 4
p a 426 b 55 c 60 2 d 108 112 680 2450 a 14 b 322 a 20 b 280 a 12 b 105 a 180 b {9} 11 20 0 a 16.5 km b 45 km c 7 walks d 189 km a 10 days b 25 per day a 86 b 2600 c 224 d 2376 e 5 extra rows $176 400 a = 15, d = 3, t6 = 0, S 6 = 45 2160 266 p p 5 11 46 5 a tn = n + b tn = 2 5n 4 4 5 n a b b (b + bn) 2 t5 = 10, S 25 = 1250 1575d a S n 1 = 23n 3n2 20 b tn = 20 6n c a = 14, d = 6
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Answers
4D ! 4 review
708 Answers 24 7, 12, 17 26 4860 27 Sequence of four positive integers such that 2a + 3d = 50; therefore a = 1 + 3t and d = 16 2t for 0 t 8. (The sequence 25, 25, 25, 25 is included.) 28 60 (the equilateral case is included with common di↵erence 0)
Exercise 4D 1 a 3, 6, 12, 24 b c 10 000, 1000, 100, 10 d 3, 9, 27, 81 5 1 2 a b c 567 256 ✓ 2 ◆n 1 3 a tn = 3 b 3 p c tn = 2( 5)n 1 2 4 a 3 b± 5 5 t9 6 a 6 b 9 c 9 2 7 5 3p 8 16 2 9 a 24 b 10 a 21870 m2 b 11 47.46 cm 12 a $5397.31 b 13 a 57.4 km b 14 $5 369 000 15 a $7092.60 b 16 $3005.61 17 18 t10 = 2048 19 20 5 weeks 21 a 60 b 2.5 c 22 3 or 1 p 1± 5 23 a = 2 24 a 168.07 mL b a+b 25 a side lengths b 2
3, 6, 12, 24
32
d a x+5
2 3 4 5 6
b
182
tn = 2( 2)
10 11 12 13 14
Exercise 4F 5 4
2 Perimeter p
3 b 5 ✓ 1 ◆n
1
2
; Area
p p2 3 ; 9 ⇥ 4n
Sum of perimeters 2p; Sum of areas d6
e 8
12 288 9th day 48th year 14th day 12 years 11.6% p.a. t6 = 729 1
d x 4 y7
20 times
p side lengths ab
57 64 c 7812 c
a 1094 b 684 10 7 a 1062.9 mL b 5692.27 mL c 11 days a 49 minutes (to nearest minute) b 164 minutes c Friday
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
8 9
481 835 ⇡ 73.44 m 6561 a $18 232.59 b $82 884.47 Bianca $3247.32; Andrew $3000 p 15 2 a 155 b + 15 2 a 8 b { n : n > 19 } x2m+2 + 1 x2 + 1 a 54976 km b 43 times Option 1: $52 million; Option 2: $45 040 000 million
1 a n 1
Exercise 4E 1 a 5115
7
p p2 3 27
3 3333 13 4 Yes 5 Yes, as the number of hours approaches infinity, but the problem becomes unrealistic after 4 to 5 hours 1 6 S1 = 8 7 2 8 12 m 9 75 m 4 1 31 7 37 10 a b c d e 1 f 9 30 3 198 9 1 11 r = , t1 = 16, t2 = 8; 2 1 r= , t1 = 48, t2 = 24 2 5 2 12 13 8 3
Chapter 4 review Technology-free questions 1 a 3, 1, 5, 9, 13, 17 b 5, 12, 26, 54, 110, 222 2 a 2, 4, 6, 8, 10, 12 b 1, 4, 7, 10, 13, 16 3 a $5250, $6037.50 b t1 = 5250, tn = 1.05(tn 1 + 500) 4 147 5 0.1 6 258.75 7 {12} 8 1 9 1000 ⇥ 1.035n 8 8 10 t2 = 6, t4 = or t2 = 6, t4 = 3 3 11 96 12 9840 3 13 14 x = 8 or x = 2 4 Multiple-choice questions 1 D 2 B 3A 6 D 7 E 8C
4 A 9 E
5B 10 D
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 709 1 13 a = 3, b = , c = 3 or 3 1 a= , b = 3, c = 3 3 14 a = 3, b = 3, c = 1 15 If c = 5, then a = 1 and b = 5; if c = 27, then a = 3 and b = 3
Exercise 5B
2
3
4 5
1 2 3 4 5 6 7 8
6
a = 10, b = 0, c = 7 a = 1, b = 2 a = 2, b = 1, c = 7 a = 2, b = 1, c = 3 (x + 2)2 4(x + 2) + 4 (x + 1)3 3(x + 1)2 + 3(x + 1) 1 a = 1, b = 2, c = 1 a It is impossible to find a, b and c such that a = 3, 3ab = 9, 3ab2 = 8 and ab3 + c = 2 b a = 3, b = 1, c = 5 9 a = 1, b = 6, c = 7, d = 1 5 10 a If a = b and a = 3b, then both a and b 3 are zero, but then a + b = 1 is not satisfied b (n + 1)(n + 2) 3(n + 1) + 1 11 a ax2 + 2abx + ab2 + c ✓ b ◆2 b2 b a x+ +c 2a 4a Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
7 8 9
10 12 13 14 15 16
b x=3 p 30 2 c x=1± d x=1± 5p 2p 3 2 13 ± 145 e x= 1± f x= 2 12 9 25 25 a m> b m< c m= 4 4 32 d m 6 or m 6 e 4 or x < , S 1 = 4 4 4x 1 p p 1 5 1+ 5 3 b i x= ii x = 2 2 4 a = 7, b = 5, c = 1 p 6 a 576 = 26 ⇥ 32 , p 576 = 24 b 1225 = 52 ⇥ 72 , p1225 = 35 c 1936 = 42 ⇥p112 , 1936 = 44 d 1296 = 64 , 1296 = 36 7 x= b c 2ab 8 x= a+b 9 (5, 14), (17, 9), (29, 4) 10 Two at $25 and four at $35 11 500 12 a 333 667 b 166 333
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Answers
6 revision
712 Answers 1 4 , b = 2, = ; 3 3 1 3 a= , b = 1, = 2 2 14 49 hours p 15 2 cm 16 192 g 8 3 17 a 5, 1 b ,0 c 3, d 14, 6 3 5 4 5 15 e 1, 9 f 4, g , 3 2 2 18 a { x : 2 x 2 } b { x : x 1} [ { x : x 1} ⇢ 1 9 c x: x d { x : 1 < x < 2} 2 2 ⇢ ⇢ 1 7 e x:x [ x:x 2 2 ⇢ 1 5 f x: x 3 3 Multiple-choice questions 1 E 2B 3 C 4D 5 B 6 A 7C 8 E 9D 10 C 11 D 12 A 13 C 14 C 15 A 16 B 17 D 18 B 19 B 20 B 21 A 22 D 23 A 24 B 25 D 26 A 27 B 28 A 29 A 30 C 31 C 32 A 33 E 34 A 35 C 36 C 37 E 38 D 39 C 40 A 13 a =
6 a a = 6000, b = 15 000 b $57 000 c 2016 7 a i 80n + 920 ii A: 2840 tonnes; B: 2465 tonnes iii 40n(n + 24) iv A: 46 080 tonnes; B: 39 083 tonnes b April 2016 8 a 4 b 6 c 8 d 2 e i 10 ii Pn = Pn 1 + 2 iii Pn = 2n + 2 1 iv 1 2
1
1 2
1 2
1 2
1 2
1
9 a 8x cm e A
1 1 4 4
1 4
1 4
1 4
b 28
1 4
1 4 11111111 88888888 1 1 1 1 111111 1 8 4 4 8 888888 8
8x cm c 7 (5, 84)
49 (2, 21) x
0
1
2
3
f A = 21 when x = 2 10 a C = 3500 + 0.5x c I/C ($)
4
5
I
b I = 1.5x d 3500
C
(3500, 5250) 3500
Extended-response questions 1 a 8 b 7.7 c 6 cm d 15 cm 2 a a = 0.4, b = 148 b C ($) c $68 d 248
0
x
e 5500 f P ($)
P represents profit
148
0
(300, 28) n
3 a b c d
i 178 ii 179 iii 179.5 i 180 ii circle 20 360 n= 180 A e square
0
x
1 25 ii x = 24 24 c 11, 24 and 39 x a r= ,x, 1 x+1 4 b i S1 = ii S 1 = 18 3 1 c x> and x , 0 2 a3 a i A= ii 4.5 6 3 a b i A1 = ii 486 12 1 1 5 c i A2 = ii a b 6 iv 99.99 v 999.999 a 14 m b tn = 1.5n d 330 m
11 b i x = 12 13
4 a Volume of hemisphere =
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
3500
-3500
iv 179.95
2 3 ⇡t , 3 Volume of cylinder = ⇡t2 s, 1 Volume of cone = ⇡t2 w 3 b i 6:2:3 ii 54⇡ cubic units R 5 a i OC1 = R r1 ii r1 = 3 R R b i OC2 = r2 ii r2 = 3 9 1 R c i r= ii rn = n 3 3 R ⇡R2 iii S 1 = iv S 1 = 2 8
2x cm
14
15
iii S 1 =
9 20
iii 30 iii 36 iii 1
11 3 c 53
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 713 ii
P (joules) (1, 49) 0
18
19 20
|x| = 76
T 13 B 21 4
5
8 7 C 18
c i 5
45 8 120 a
8
9
8 9
7
9
7
1 1, 1, 2, 6, 24, 120, 720, 5040, 40 320, 362 880, 3 628 800 2 a 5 b 90 c 66 d 161 700 n+2 3 a n+1 b n+2 c n(n 1) d (n + 1)! 4 1, 4, 12, 24, 24 5 DOG, DGO, ODG, OGD, GOD, GDO 6 120 7 362 880 8 FR, FO, FG, RF, RO, RG, OF, OR, OG, GF, GR, GO 9 a 720 b 720 c 360 10 a 120 b 120 c 60 11 20 160 12 a 125 b 60 13 a 120 b 360 c 720 14 60 15 a 17 576 000 b 11 232 000 16 a 384 b 3072 17 (m, n) = (6, 0), (6, 1), (5, 3) 18 (n2 n) · (n 2)! = n · (n 1) · (n 2)! = n! 19 30
1 2 3 4 5 6 7 8 9 10 11
Exercise 7A
7
Exercise 7B
Exercise 7C
ii 0
Chapter 7 1 2 3 4
a 6 b 18 c 20 d 15 BB, BR, BG, RB, RG, GB, GR, GG 12 9 a 6 b 13 16
7A ! 7D
17
h (m)
iii 1136.8 b i P = 9.8mh ii 100% increase iii 50% decrease c i 14 ii 42 d4 a i a = 50 000, d = 5000 ii 11th month iii 4 950 000 litres b i qn = 12 000(1.1)n 1 ii 256 611 litres c 31st month a i 15.4 million tonnes ii 21.7 million tonnes b tn = 0.9n + 9.1 c 371 million tonnes d 11.1 years e Pn = 12.5(1.05)n 1 f 14.2 years a 1 hour 35 minutes b 2.5 km a |B0 \ C 0 \ T | = |C \ T |, |B \ C 0 \ T 0 | = 3|B0 \ C \ T 0 |, |B \ C 0 \ T | = 4 b
7 8 9 10 11 12
Answers
16 a i P = 49h
8
a 120 a 120 a 360 a 1152 a 600 a 720 a 900 84 32 a 480 144
b b b b b b b
72 48 144 1152 108 48 900
c 24 c 72 c 144
d 96 d 12 d 72
c 431 c 144
d 52 d 96
e 48
b 192
Exercise 7D
b 7 7
8
5 a 27 6 30 Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
9
8 9
7
8
b6
9
7
8
9
1 3 5 6 7
35 4 989 600 27 720 a 420 b 105 35
2 34 650 4 56 c 90
d 12
e 105
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7E ! 7H
714 Answers 8 a 15 9 a 52!
(m + n)! m! · n! 104! b (2!)52 b
c
(52n)! (n!)52
10 4900 11 89
Answers
Exercise 7E 1 1, 5, 10, 10, 5, 1 2 a 7 b6 c 66 d 56 e 100 f 499 500 n(n 1) 3 a n b c n d n+1 2 (n + 2)(n + 1) n(n + 1) e f 2 2 4 a 720 b 120 5 2 598 960 6 a 10 b 45 c 45 d 10 7 45 379 620 8 56 9 a 45 b 16 10 15 n! 11 n Cn r = (n r)! (n (n r))! n! = = nCr (n r)! r! 12 Each diagonal is obtained by choosing 2 vertices from n vertices. This can be done in n C2 ways. But n of these choices define a side of the polygon, not a diagonal. Therefore there are n C2 n diagonals. 13 There are 10 C5 ways to choose 5 students for team A. The remaining 5 students will belong to team B. However, the labelling of the teams does not matter, so we must divide by 2. 14 462 15 n 1 Cr 1 + n 1 Cr (n 1)! (n 1)! = + (r 1)! (n 1 (r 1))! r! (n 1 r)! (n 1)! (n 1)! = + (r 1)! (n r)! r! (n r 1)! ✓ 1 (n 1)! 1◆ = + (r 1)! (n r 1)! n r r (n 1)! n = · (r 1)! (n r 1)! r(n r) n! = = nCr r! (n r)! 16 a 2300 b 152 c 2148
Exercise 7F 1 153 3 1176 5 a 1716
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b 700
2 126 4 140 c 980
d 1568
6 7 8 9 10 11 12 13 15 17
a 25 200 b 4200 a 1 392 554 592 b a 15 504 b 10 800 c a 21 b 10 c 2100 a 204 490 b 7 250 100 a 48 b 210 1440 14 14 400 16 3744
5 250 960 15 252 11
3600 150
Exercise 7G 1 7 C2 = 21, 6 C2 = 15, 6 C1 = 6 2 1, 7, 21, 35, 35, 21, 7, 1; 7 C2 = 21, 7 C4 = 35 3 1, 8, 28, 56, 70, 56, 28, 8, 1; 8 C4 = 70, 8 C6 = 28 4 26 = 64 5 25 = 32 10 6 2 = 1024 7 26 1 = 63 8 8 8 8 2 C1 C0 = 247 9 28 = 256 10 24 1 = 15 11 a 128 b 44
Exercise 7H 1 4 2 Label 26 holes from A to Z. Put each of the 27 words into the hole labelled by its first letter. Some hole contains at least two words. 3 Label 4 holes by 0, 1, 2, 3. Put each of the 5 numbers into the hole labelled by its remainder when divided by 4. Some hole contains at least two numbers. 4 a 3 b 5 c 14 5 Divide [0, 1] into 10 subintervals: [0, 0.1), [0.1, 0.2), . . . , [0.9, 1]. Some interval contains at least two of the 11 numbers. 6 Divide into 4 equilateral triangles of side length 1 unit as shown. Some triangle contains at least two of the 5 points. 7 Divide the rectangle into squares of size 2 ⇥ 2. There are 12 squares and 13 points, so some square contains at least two points. The distance between two points in the same square cannot p exceed the p length of the square’s diagonal, 22 + 22 = 2 2. 8 a For two-digit numbers, the possible digital sums are 1, 2, . . . , 18. Since 19 > 18, some digital sum occurs at least twice. b For three-digit numbers, the possible digital sums are 1, 2, . . . , 27. Since 82 = 3 ⇥ 27 + 1, some digital sum occurs at least 4 times.
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Answers 715
1 a {1, 3, 4} b {1, 3, 4, 5, 6} c {4} d {1, 2, 3, 4, 5, 6} e3 f ?, {4}, {5}, {6}, {4, 5}, {4, 6}, {5, 6}, {4, 5, 6} 2 36 34 4 150 5 a 64 b 32 6 a 48 b 48 c 12 d 84 7 a 12 b 38 8 88 9 80 10 4 11 a 756 b 700 c 360 d 1096 12 1 452 555 13 3417 14 10
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Technology-free questions 1 a 20 b 190 c 2 11 3 a 27 b 6 4 120 5 6 18 7 8 10 9 10 12 11
300
d 4950
60 31 3 192
Multiple-choice questions 1 C 2 B 3 A 4 D 5 B 7 C 8 D 9 C 10 C 11 A Extended-response questions 1 a 120 b 360 c 72 2 a 20 b 80 c 60 3 a 210 b 84 c 90 4 a 420 b 15 c 105 5 a i 20 ii 10 iii 64 b 8 6 a 210 b 100 c 10 7 a 676 b 235 c 74 8 a 24
b 4
c 24
6 B
d 144
7I ! 9A
Exercise 7I
Chapter 7 review
Answers
9 Label 4 holes by 0, 1, 2, 3. Place each number into the hole labelled by its remainder when divided by 4. Since 13 = 3 ⇥ 4 + 1, some hole contains at least 4 numbers. 10 Two teams can be chosen in 8 C2 = 28 ways. Since there are 29 games, some pair of teams play each other at least twice. 11 At least 26 students. To show that 26 numbers suffice, label 25 holes by (1 or 49), (2 or 48), . . . , (24 or 26), (25). To show that 25 numbers do not, consider 1, 2, 3, . . . , 25. 12 Label the chairs 1, 2, . . . , 14. There are 14 groups of three consecutive chairs: {1, 2, 3}, {2, 3, 4}, . . . , {13, 14, 1}, {14, 1, 2} Each of the 10 people belongs to 3 groups, so there are 30 people to be allocated to 14 groups. Since 30 2 ⇥ 14 + 1, some group contain at least 3 people. 13 Draw a diameter through one of the 4 points. This creates 2 half circles. One half circle contains at least two of the 3 remaining points (and the chosen point). 14 There are 195 possible sums: 3, 4, . . . , 197. There are 35 C2 = 595 ways to choose a pair of players. Since 595 3 ⇥ 195 + 1, at least 4 pairs have the same sum. 15 Label the chairs 1, 2, . . . , 12. There are 6 pairs of opposite seats: {1, 7}, {2, 8}, {3, 9}, {4, 10}, {5, 11}, {6, 12} Some pair contains two of the 7 boys. 16 Label n holes by 0, 1, 2, . . . , n 1. Place each guest in the hole labelled by the number of hands they shake. The first or last hole must be empty. (If a guest shakes 0 hands, then no guest shakes n hands. If a guest shakes n hands, then no guest shakes 0 hands.) This leaves n 1 holes, so some hole contains at least two guests.
d 195 d 12
d 80 d
3 4
9 a 924 b There are at least 365 ⇥ 3 = 1095 days in three years and there are 924 di↵erent paths, so some path is taken at least twice. c i 6 ii 70 iii 420 d 624 10 196
Chapter 8 See solutions supplement
Chapter 9 Exercise 9A 1 a i obtuse ii straight iii acute iv right b i \HFB ii \BFE iii \HFG iv \BFE c i \CBD, \BFE, \ABF, \HFG ii \CBA, \BFH, \DBF, \EFG 2 a a = 65 , b = 65 b x = 40 , y = 130 c a = 60 , b = 70 , c = 50 , d = 60 , e = 50 , f = 130 d ↵ = 60 , = 120 e ↵ = 90 , = 93 f ↵ = 108 , = 90 , ✓ = 108
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Answers
9B ! 9H
716 Answers 4 a \B = \D = 180 ↵ 9 a ✓ = 107 b ✓ = 55
b \C = ↵
Exercise 9B 1 2 3 4 6
a Yes b Yes c Yes d No a Scalene b Isosceles c Equilateral Must be greater than 10 cm a 6, 6.5, 7 b No a ✓ = 46 , straight angle; = 70 , complementary to \EBC; = 64 , alternate angles (\CBD); ↵ = 46 , corresponding angles (\EBD) b = 80 , angle sum of triangle; = 80 , vertically opposite ( ); ✓ = 100 , supplementary to ; ↵ = 40 , alternate angles (\BAD) c ↵ = 130 , supplementary to \ADC; = 65 , co-interior angles \CDA; = 65 , co-interior angles \ACD d ↵ = 60 , equilateral triangle e ↵ = 60 , straight angle; = 60 , angle sum of triangle f a = 55 , straight angle; b = 55 , corresponding angles (a); g = 45 , vertically opposite; c = 80 , angle sum of triangle; e = 100 , straight angle; f = 80 , corresponding angles (c) g m = 68 , corresponding angles; n = 60 , angle sum of triangle; p = 52 , straight angle; q = 60 , alternate angles (n); r = 68 , alternate angles (m) 7 a Sum = 720 ; Angles = 120 b Sum = 1800 ; Angles = 150 c Sum = 3240 ; Angles = 162 8 a Together they form 10 straight angles b 360 10 10
Exercise 9C 1 a b c 2 a b c d e f 6 a 7 a
A and C (SAS) All of them (AAS) A and B (SSS) 4ABC ⌘ 4CDA (SSS) 4CBA ⌘ 4CDE (SAS) 4CAD ⌘ 4CAB (SAS) 4ADC ⌘ 4CBA (RHS) 4DAB ⌘ 4DCB (SSS) 4DAB ⌘ 4DBC (SAS) a = b = c = d = 60 a = 108 , b = 36 , c = 72 , d = 36 , e = 36 , f = 36
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Exercise 9D 1 3 5 6 8 12 15
16.58 m 2 13.9 cm 4 a 50 cm2 b 32 cm2 p 2p5 cm 7 2 6 ⇡ 4.9 cm 9 13.86 cm 14 x = 1.375, y = 2.67 16
41 m 18.38 cm 2 cm2 b, d XY p = 2.8 cm 3 2 cm
Exercise 9E 1 2 3 5 7 9 10
2 parts = 2000, 7 parts = 7000 1 part = 3000, 2 parts = 6000 3.6 4 264 22.5 6 60 , 50 , 70 $14 8 30 g zinc, 40 g tin 16 white beads, 8 green beads 5.625 km 11 $1200 3 12 13 ⇡ : 1 5 14 1 : 1 15 6 : 7 16 8.75 km
Exercise 9F 1 a AAA, 11.25 cm c AAA, 3 cm 2 a AAA, 6 cm c AAA, 2 23 cm 3 AC = 17.5, AE = 16, 4 4.42 m 6 15 m 8 10 10 m 31 10 83.6 cm 12 40 17 m 14 1 14 m 15
b AAA, 11 23 cm d AAA, 7.5 cm b AAA, 1 13 cm d AAA, 7.5 cm AB = 20 5 7.5 m 7 22.5 m 9 x = 6 23 39 11 x = 46 13 7.2 m
p p 15 b x = 10 c y = 2 5, z = 5 5 36 16 a = 17 7.11 m 7 18 1.6 cm 19 2 17 m p p 20 a = 3 5, x = 5, y = 2 5
Exercise 9G See solutions supplement
Exercise 9H 1 a 1:2:3:4 b 1 : 4 : 9 : 16 c Yes, second ratio is the square of the first 2 a 1:2:3:4 b 1 : 4 : 9 : 16 c Yes, second ratio is the square of the first 3 19 49 cm2 4 4.54 cm2 p p 4 3 4 5 a 3 cm b cm c 3 3
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Answers 717
2b i 4 4 a i 36 c 0.62
c 48 cm b 1.6 m2
16 a 2% b 3% 1 1 2 17 a b c 3 3 3
c d
8 3 m 27 2 3
Multiple-choice questions 1 C 2 B 3B 6 D 7 B 8D 11 D 12 C 13 E
e
1 9
f
4 B 9 C 14 E
Extended-response questions h x 1 a 4EBC c = q x+y 2 a Rhombus; CF = 1
c 1000 cm3
4 9
5A 10 B 15 E
20 9 p 1+ 5 c 4ACF e 2 e
3 x = 8 or x = 11 4 a 4 BDR and 4CDS ; 4 BDT and 4 BCS ; 4RS B and 4DS T z p z q b = c = y p+q x p+q 1 9 5 a i 9 cm ii 12 cm iii iv 16 16 b i 16a cm2 ii 3a cm2 p 7 15 26 m
Chapter 10
p ii 10 ii 72
Exercise 10A
p p 1+ 5 3+ 5 , '2 = , 2 2 p p p 7+3 5 5 1 3 4 1 ' = 2 + 5, ' = , ' = , 2 2 p p p 3 5 7 3 5 ' 2= , ' 3 = 5 2, ' 4 = 2 2
5 '0 = 1, '1 =
Chapter 9 review Technology-free questions 1 a rectangle b 16 cm p 3 34 cm 4 a x = 7 cm, y = 7 cm, ↵ = 45 , = 40 b ↵ = 125 , = 27.5 c ✓ = 52 , ↵ = 52 , = 65 , = 63 5 8m 7 b i 20 cm ii 10 cm c XP : PY = 2 : 1, PQ : YZ = 2 : 3 8 a 3 cm b 5:3 c 3:5 210 15 m 10 9 23 8
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
15 a 20 : 3
12 12 b 2:1
9I ! 10B
Exercise 9I
11 12.25 13 a 96 g d 100 mm 14 b 25 : 36
Answers
6 4:5 7 22.5 8 a 1:2:3 b 1:2:3 c 1 : 8 : 27 d Yes, the third ratio is the cube of the first 9 a i 2 : 3 ii 2 : 3 iii 2 : 3 b 8 : 27 c Yes, the ratios in a are cubed to form the ratios in b 10 a 3 : 2 : 5 32 500 b Volumes (in cm3 ) are 36⇡, ⇡ and ⇡; 3 3 Ratio of volumes is 27 : 8 : 125 c Yes, the ratios in a are cubed to form the ratios in b 11 8 : 1 12 27 : 64 13 2 : 3 14 a 4 : 3 b 4:3 15 a 4 : 1 b 8:1 16 a 1 : 100 b 1 : 1000 c 1 : 10 d 1:1 27 17 litres, 4 litres 16 18 125 mL, 216 mL 19 a 1 : 50 b 1 : 125 000 c 3 cm d 7500 cm2 20 a 12 : 13 b 1728 : 2197 21 a 4 b 3.75 22 3 : 4 23 4.5 cm
1 a x = 100, y = 50 b x = 126, y = 252, z = 54 c y = 145, z = 290 d x = 180, y = 90 e x = 45, y = 90, z = 270 2 a x = 68, y = 121 b x = 112, y = 87 c x = 50, y = 110 3 110 , 110 , 140 4 \ABC = 98 , \BCD = 132 , \CDE = 117 , \DEA = 110 , \EAB = 83 7 60 or 120 8 \P = 78 , \Q = 72 , \R = 102 , \S = 108
Exercise 10B 1 a x = 73, y = 81 b x = 57, q = 57 c x = 53, y = 74, z = 53 d x = 60, y = 60, z = 20, w = 100 e w = 54, x = 54, y = 72, z = 54 2 a 40 b 40 c 80 3 32 and 148 4 \ACB = 40 , \ABC = 70 , \BAT = 40
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Answers
10C ! 12A
718 Answers Exercise 10C 1 2 3
a 10 cm 7 cm p 5 6 cm
b 6 cm
Chapter 10 review Technology-free questions 1 \MCN = 18 2 a x = 110, y = 70 b x = 35, y = 35 c x = 47, y = 53, z = 100 d x = 40, y = 40, z = 70 6 a x = 66 b x = 116 c x = 66, y = 114 8 3 cm Multiple-choice questions 1 B 2 A 3 E 6 A 7 C 8 B
4 A 9 A
5C 10 A
Extended-response questions 5 b 24 cm2
Chapter 11 Technology-free questions 1 24 2 360 3 a 125 b 60 4 a 9 b 25 5 a 24 b 30 c 28 d 6 a 120 b 120 7 a 120 b 36 8 a 96 b 24 c 72 d 9 10 10 a 20 b 325 c 210 d 11 a 28 b 21 c 28 = 256 12 60 13 120 14 7 15 51 16 80 19 a If n is odd, then 5n + 3 is even. c If n is even, then 5n + 3 is odd. 26 a 90 b 54 c 80 d e x = 96 , y = 70 f 46 27 a 40 b 140 c 50 28 a 38 b 52p c 68 3 10 29 a 4 b c 12 2 31 a 156 b 144 c 25 32 30 35 Yes
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
45
60 56
Multiple-choice questions 1 A 2 C 3C 6 D 7 D 8D 11 B 12 E 13 E 16 E 17 E 18 B 21 D 22 A 23 E 26 E 27 A 28 C 31 D 32 B 33 C 36 C 37 C 38 B
4 9 14 19 24 29 34 39
A A D B C C B D
5 10 15 20 25 30 35
B E C D B E D
Extended-response questions 1 a 2160 b 360 c 900 d 1260 2 a 70 b 30 c 15 d 55 3 a 20 b 4 c 68 4 a 420 b 60 c 120 d 24 5 a 300 b 10 and 15 6 a 495 b 60 c The two points diametrically opposite 1 d 15 e 33 7 a No b Yes; both a and b are odd, and c is even 8 a (a, b, c) = (2, 3, 6) b (a, b, c, d) = (1, 2, 3, 4) or (a, b, c, d) = (1, 2, 3, 5) 10 a 10 11 a 49, 50, 51 and 52 b 93 and 94 d 44 12 b 21 coins c 10 14 a No b n = 4k or n = 4k 1 16 a a = 1, b = 3, c = 1 c 412 2 1 a 1 a2 18 b c d e 2 8 4 32 1 2 ✓ 1 ◆n 1 2 2 1 2n f i An = a =a ⇥2 ii a2 2 4 3 19 b \BCA = x , \BOA = 2x , \T AB = x , \T BA = x
Chapter 12 Exercise 12A 220
1 No, the sample is biased towards students who use the internet, because of the email collection method. 2 No, the sample is biased because she is collecting the data at a particular time of day. Some age groups would be more likely to use the restaurant at that time – probably school children and ‘young’ families. 3 No, the sample is biased towards viewers of that station. Only people with strong opinions will call, and people may call more than once. 4 Answers will vary 5 a 0.48 b pˆ
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Answers 719
Exercise 12B 1 a
f 3 a d 4 a c
d 5 a b c
d e 6 a b c
d e 7 a b 8 a b c
c 0.307 d Pr(Pˆ < 0.3 | Pˆ < 0.8) = 0.1053 1 1 3 1 5 3 7 10 a 0, , , , , , , , 1 8 4 8 2 8 4 8 1 b pˆ 0 Pr(Pˆ = p) ˆ
pˆ 0.8 0.9 1 Pr(Pˆ = p) ˆ 0.0440 0.0098 0.00098
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1 4
8
0.000003
0.00008
0.00115
pˆ Pr(Pˆ = p) ˆ
3 8
1 2
5 8
0.0092
0.0459
0.1468
pˆ Pr(Pˆ = p) ˆ
3 4
7 8
0.2936
0.3355
1 0.1678
c 0.9437 d Pr(Pˆ > 0.6 | Pˆ > 0.25) = 0.9448 11 a pˆ 0 0.25 0.5 0.75
1 Hyp 0.0587 0.2499 0.3827 0.2499 0.0587 Bin 0.0625 0.25 0.375 0.25 0.0625
b
pˆ 0 0.2 0.5 Pr(Pˆ = p) ˆ 0.2274 0.4263 0.2713
pˆ 0.4 0.5 0.6 0.7 Pr(Pˆ = p) ˆ 0.2051 0.2461 0.2051 0.1172
1 2
2 5 pˆ 1 3 6 Pr(Pˆ = p) ˆ 0.2527 0.1095 0.0198
pˆ 0.6 0.8 1 Pr(Pˆ = p) ˆ 0.3973 0.2554 0.0511 Pr(Pˆ > 0.7) = 0.3065 Pr(0 < Pˆ < 0.8) = 0.6899, Pr(Pˆ < 0.8 | Pˆ > 0) = 0.6924 p = 0.2 0, 0.25, 0.5, 0.75, 1
pˆ 0 0.1 0.2 0.3 Pr(Pˆ = p) ˆ 0.00098 0.0098 0.0440 0.1172
1 3
Pr(Pˆ = p) ˆ 0.0122 0.0795 0.2153 0.3110
pˆ 0 0.2 0.4 Pr(Pˆ = p) ˆ 0.0036 0.0542 0.2384
pˆ 0.75 1 Pr(Pˆ = p) ˆ 0.0691 0.0059 Pr(Pˆ > 0.5) = 0.075 Pr(0 < Pˆ < 0.5) = 0.4263, Pr(Pˆ < 0.5 | Pˆ > 0) = 0.5518 0.028 Pr(0 < Pˆ < 0.6) = 0.243, Pr(Pˆ < 0.6 | Pˆ > 0) = 0.897 p = 0.5 0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1
1 6
12B ! 12D
b 2 a c d e
x 0 1 2 Pr(X = x) 0.16 0.48 0.36 Pr(X 1) = 0.84 Pr(X = 3) = 0.35 b Pr(X < 3) = 0.20 Pr(X 4) = 0.45 Pr(1 < X < 5) = 0.75 Pr(X , 5) = 0.85 15 Pr(1 < X < 5 | X > 1) = 19 0.0034 b 0.0035 c 0.7342 0.2533 e 0.2567 f 0.2654 1 2 p = 0.5 b 0, , , 1 3 3 1 2 pˆ 0 1 3 3 Pr(Pˆ = p) ˆ 0.1 0.4 0.4 0.1 0.9 p = 0.6 0, 0.2, 0.4, 0.6, 0.8, 1
d Pr(Pˆ > 0.5) = 0.3771 1 1 1 2 5 9 a 0, , , , , , 1 6 3 2 3 6 b pˆ 0
Answers
6 a All students at the school b 0.42 c 0.37 7 a All Australian adults b 4 c 3.5
pˆ Hyp Bin
0 0.0006 0.00098
0.1 0.0072 0.0098
0.2 0.0380 0.0440
pˆ Hyp Bin
0.4 0.2114 0.2051
0.5 0.2593 0.2461
0.6 0.2114 0.2051
pˆ Hyp Bin
0.8 0.0380 0.0440
0.9 0.0072 0.0098
1 0.0006 0.00098
0.3 0.1131 0.1172 0.7 0.1131 0.1172
c Not much
Exercise 12C 1 2 3 4 5 6
a a c c c c
Pr(Pˆ 0.8) = 0.08 b Pr(Pˆ 0.5) = 0.01 Pr(Pˆ 0.7) = 0.01 b Pr(Pˆ 0.25) = 0.07 i ⇡ 0.04 ii ⇡ 0.01 i ⇡ 0.04 ii ⇡ 0.04 i ⇡ 0.06 ii ⇡ 0.13 i ⇡ 0.01 ii ⇡ 0.06
Exercise 12D 1 2 3 4 5 6
a a c c c c
Pr(X¯ 25) = 0.02 b Pr(X¯ 23) = 0.01 Pr(X¯ 163) = 0.04 b Pr(X¯ 158) = 0.05 i ⇡ 0.04 ii ⇡ 0.04 i ⇡ 0.02 ii ⇡ 0.01 i ⇡ 0.07 ii ⇡ 0.01 i ⇡ 0 ii ⇡ 0
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Answers
12 review ! 13C
720 Answers
Chapter 13
Chapter 12 review Technology-free questions 1 a Employees of the company b 0.35 c 0.4 2 No, this sample (people already interested in yoga) is not representative of the population 3 No, people who choose to live in houses with gardens may not be representative of the population 4 a People with Type II diabetes b Population is too large and dispersed c Unknown d x¯ = 1.5 5 a Employees of the company b p = 0.2 c pˆ = 0.22 3 1 2 6 a p= b , ,1 5 3 3 c 1 2 pˆ 1 3 3 3 6 1 Pr(Pˆ = p) ˆ 10 10 10 7 d Pr(Pˆ > 0.5) = 10 3 e Pr(0 < Pˆ < 0.5) = , 10 3 Pr(Pˆ < 0.5 | Pˆ > 0) = 10 7 a 0, 0.25, 0.5, 0.75, 1 b pˆ 0 0.25 0.5 0.75 1 Pr(Pˆ = p) ˆ 0.0625 0.25 0.375 0.25 0.0625
c Pr(Pˆ < 0.5) = 0.3125 1 d Pr(Pˆ < 0.5 | Pˆ < 0.8) = 3 8 a i Pr(Pˆ 0.7) = 0.03 ii Pr(Pˆ 0.38) = 0.04 b i 0.42 ii 0.08 Multiple-choice questions 1 B 2 C 3 A 4 B 5B 6E 7 A 8 D 9 E 10 B 11 C 12 E Extended-response questions 1 a p a b
b 2 a b c
0.1 0.03 0.17 0.2 0.11 0.29 0.3 0.19 0.41 0.4 0.29 0.51 0.5 0.38 0.62 0.6 0.49 0.71 i pˆ = 0.34 ii p = 0.3 or p = 0.4 iii mean ⇡ 50, s.d. ⇡ 1.12 iii mean ⇡ 50, s.d. ⇡ 0.71 iii mean ⇡ 50, s.d. ⇡ 0.50
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Exercise 13A 1 a 4.10 d 4.08 p 40 3 2 cm 3 3 66.42 , 66.42 4 23 m 5 a 9.59 b 6 a 60 b 7 a 6.84 m b 8 12.51 9 182.7 m 10 1451 m p 11 a 5 2 cm b 12 3.07 cm 14 31.24 m
b 0.87 e 33.69
, 47.16 p 35 m 17.32 m 6.15 m
90
16 57.74 m 18
c 2.94 f 11.92
10 p ⇡ 3.66 1+ 3
13 37.8 cm 15 4.38 m p 2 3 17 p ⇡ 12.93 m 2 3 19 \APB = 47.16
Exercise 13B 1 a 8.15 b 3.98 c 11.75 d 9.46 2 a 56.32 b 36.22 c 49.54 d 98.16 or 5.84 3 a A = 48 , b = 13.84, c = 15.44 b a = 7.26, C = 56.45 , c = 6.26 c B = 19.8 , b = 4.66, c = 8.27 d C = 117 , b = 24.68, c = 34.21 e C = 30 , a = 5.40, c = 15.56 4 a B = 59.12 , A = 72.63 , a = 19.57 or B = 120.88 , A = 10.87 , a = 3.87 b C = 26.69 , A = 24.31 , a = 4.18 c B = 55.77 , C = 95.88 , c = 17.81 or B = 124.23 , C = 27.42 , c = 8.24 5 554.26 m 6 35.64 m 7 1659.86 m 8 a 26.60 m b 75.12 m
Exercise 13C 1 5.93 cm 2 \ABC = 97.90 , \ACB = 52.41 3 a 26 b 11.74 c 49.29 e 68.70 f 47.22 g 7.59 4 2.626 km 5 3.23 km 6 55.93 cm 7 a 8.23 cm b 3.77 cm
d 73 h 38.05
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Answers 721 b 5.53 cm b 64.46 b 67.7 m
Exercise 13D 11.28 cm2 b 15.10 cm2 10.99 cm2 d 9.58 cm2 6.267 cm2 b 15.754 cm2 19.015 cm2 d 13.274 cm2 2 24.105 cm or 29.401 cm2 2.069 cm2
Exercise 13E 1 45.81 cm 2 a 95.5 3 a 6.20 cm 4
b 112.88 b 2.73 cm2 y
4
B
y=2
2 −4
x
4
0 A −4
5 6 7 8 9 10 11
Area of A \ B = 9.83 square units 61.42 cm2 a 125.66 m b 41.96% a 10.47 m b 20.94 m2 2 6.64 cm ✓ 18 ◆c ✓ 14 ◆c r = 7 cm, ✓ = or r = 9 cm, ✓ = 7 9 247.33 cm a 81.96 cm b 4.03 cm2
Exercise 13F 1 3 5 7 8 9 11 12 13
400.10 m 575.18 m 16.51 m a 034 a 3583.04 m 027 22.01 a \BAC = 49 10.63 km
2 4 6 b b 10
34.77 m 109.90 m 056 214 353 113
b 264.24 km
Exercise 13G 1 a c 2 a d
13 cm 31.61 4 cm 13.27 cm
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b 15.26 cm d 38.17 b 71.57 c 12.65 cm e 72.45 f 266.39 cm2
10.31 at B; 14.43 at A and C a 85 m b 45.04 m 17.58 1702.55 m a 24.78 b 65.22 c 20.44 42.40 m 1945.54 m a 6.96 cm b 16.25 cm2 a 5 km b 215.65 c 6.55
Exercise 13H 1 a 4a2 , 3a2 and 12a2 square units respectively b 14.04 c 18.43 d 11.31 2 a 35.26 b 45 3 a 0.28 b 15.78 4 a 15.51 cm b 20 cm c 45.64 5 a i 107 m ii 87 m iii 138 m b 43.00 p 6 a 5 11 cm b 64.76 c 71.57 d 95.74 7 26.57 8 a 54.74 b 70.53 9 1.67 km 10 a 141.42 m b 20.70 11 16 cm 12 34.14 p cm a 3 a 13 a cm b cm 2 2 14 a 26.57 b 39.81 c 38.66
13D ! 13 review
1 a c 2 a c e f
3 4 5 6 7 8 9 10 11
Answers
8 a 7.326 cm 9 a 83.62 10 a 87.61 m
Chapter 13 review Technology-free questions p p 1 a 5 3± ✓ 5 ◆11 ✓5◆ or ⇡ sin 1 b sin 1 6 6 p 2 a 20 3 cm b 20 cm p 3 4 19 km p p 25 3 4 a 5 3 cm b cm2 4 p 105 5(21 + 5 3) c cm2 d cm2 4 4 5 143 17 6 28 p 3 93 7 31 ✓ 11 ◆c 8 6 9 a i 30 ii 15 p p p b AT = 300(1 + 3) m, BT = 150( 6 + 2) m p 10 181 km
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
14A ! 14B
722 Answers p 12 3 km, BC = 2.4 km 5 b 57.6 km/h 180 cm2 21.4 cm ✓ 12 ◆ a 26 tan 1 cm 5 ✓ ◆◆ ✓ 12 b 169 ⇡ tan 1 cm2 5 11 m
3 a
11 a AC = 12 13 14
15
Multiple-choice questions 1 D 2C 3 C 6 A 7D 8 B
y 4 2
p 4
0
p 2
3p 4
p
x
-2 -4
b 4B 9C
5 A 10 A
Extended-response questions 1 a \ACB = 12 , \CBO = 53 , \CBA = 127 b 189.33 m c 113.94 m 2 a 4.77 cm b 180 cm2 c 9.55 cm 3 a \T AB = 3 , \ABT = 97 , \AT B = 80 b 2069.87 m c 252.25 m 4 a 184.78 m b 199.71 m c 14.93 m 5 a 370.17 m b 287.94 m c 185.08 m p 6 a 8 2 cm b 10 cm c 10 cm d 68.90 L2 sin ↵ sin sin 7 Area = 2(sin ↵ + sin + sin )2
Chapter 14
y
5 π 6
-5
c
π 3
x
π 2
y
π 4
d
π 2
3π 4
x
π
y
Exercise 14A 1 1 d1 p b p c 1 2 2 p 1 3 f p g 0 h i0 2 2 1 k1 l 0 m n 1 2 2 a 0.6 b 0.6 c 0.3 e 0.3 f 0.6 g 0.6
10
1 e p 2
1 a
-10
j 0 o d h
1
e
0.3 0.3
y
5
Exercise 14B 3⇡ 7⇡ ⇡ 4⇡ 1 a , b , 4 4 3 3 7⇡ 3⇡ ⇡ 5⇡ d , , , e 8 8 8 8 7⇡ ⇡ 5⇡ 11⇡ f , , , 12 12 12 12
⇡ c , 6 5⇡ ⇡ , , 6 3
7⇡ 6 ⇡ 2⇡ , 6 3
3⇡ 7⇡ 11⇡ 15⇡ 2 a , , , 8 8 8 8 7⇡ 3⇡ ⇡ 5⇡ b , , , 8 8 8 8 13⇡ 7⇡ ⇡ 5⇡ 11⇡ 17⇡ c , , , , , d 18 18 18 18 18 18
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x
π
π 2
π
2π
x
-5
f
y
4 2 0
⇡ 6
-2
p 4
3p 4
p
x 5p 7p 2p 4 4
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 723 Exercise 14D
y 4 3 2 1 0 -1 -2
2 π 2
3π 2
2π
π
3π 2
2π
3
4 2 0
π 2
–2
i
x
4
y 2
5 0
π 4
–2
π 2
π
3π 4
x
6 7
–4
Exercise 14C 1 a
1
e
2
2 a
1
1 d p 3 g
1
p
2 2 c p = 3 1 f 2 g p = 3 p 2 2 3 b p = 3 p 3 p 3 = e 2 3 p 2 2 3 h p = 3 3
3 a
⇡ 5⇡ , 6 6
4 a
8 17
b
b
⇡ 7⇡ , 6 6 b
d 1 h 2
c 1
p 2 2 3 f p = 3 p3 1 3 i p = 3 3 3⇡ 5⇡ ⇡ 5⇡ c , d , 4 4 4 4
15 17
24 7 5 cos ✓ = , sin ✓ = 25 25 p 29 6 5 8 7 31 p 15 15(6 5) 8 p = 124 4(9 + 5)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
p 2 3 3 p 3 3
c
15 8
8 a
p
63 16
b
24 7
7 3 b 25 5 p 3 5⇡ 10 a for ✓ = 2 3 11 a 1 sin(2✓) 9 a
c
56 65
d
c
117 44
d
14C ! 14E
π
x
y
h
p p p p 2+ 6 1 3 2 6 b p = 4 4 2 2 p p p p 6 2 3+1 a b p =2+ 3 4 3 1 p p p 3 1 6 2 a p = 4 2 2 p p p 3 1 6 2 b p = 4 2 2 p p 1 3 c p = 2+ 3 1+ 3 ⇣ ⇡⌘ 63 For u, v 2 0, , sin(u + v) = ; 2 65 ⇣⇡ ⌘ 63 For u, v 2 , ⇡ , sin(u + v) = ; 2 65 ⇣ ⇡⌘ ⇣⇡ ⌘ 33 For u 2 0, , v 2 , ⇡ , sin(u + v) = ; 2 2 65 ⇣⇡ ⌘ ⇣ ⇡⌘ 33 For u 2 , ⇡ , v 2 0, , sin(u + v) = 2 2 65 p 3 1 1 a sin ✓ + cos ✓ b p (cos ' + sin ') 2 2 2 p tan ✓ + 3 1 c d p (sin ✓ cos ✓) p 1 3 tan ✓ 2 a sin u b cos u 119 24 24 169 a b c d 169 25 7 119 33 16 65 7 e f g h 65 65 33 24
1 a
Answers
g
24 25 336 625
1 2 b cos(2✓) b
Exercise 14E 1 a 5, p 5p c p 2, 2p e 2 3, 2 3 g 4, 0
b d f h
⇡ ,⇡ 2 ⇡ 3⇡ c , 6 2 e 53.13 ✓ ⇡◆ 3 2 cos 2x + 6 ✓ p 5⇡ ◆ 4 2 sin 3x 4
b 0,
2 a
2, p 2p 2, 2 2, p 2 5 + 13, 5
p 13
2⇡ , 2⇡ 3 5⇡ d 0, , 2⇡ 3 f 95.26 , 155.26
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
14 review
724 Answers ✓ p 3⇡ ◆ cos x = 2 cos x 4 ✓ ✓ p 7⇡ ◆ p ⇡◆ = 2 sin x + = 2 sin x 4 4
5 a f (x) = sin x
y
Answers
√2
6 a
π 4
0
⇡ 7⇡ 9⇡ 15⇡ , , , 8 8 8 8 4 60 , 300 , 0 , 180 , 360 140 21 b 5 a 221 221 h
5π 4
7π 4
3π π 4
−1 −√2
7 a 8 a
x 2π
p b f (x) = 3 sin x + cos x ✓ ✓ ⇡◆ ⇡◆ = 2 cos x = 2 sin x + 3 6 y
10 a 12 a 13 a d
2
π 3
1 0
5π 6
4π 3
11π 6
π
f
x
2π
14 a
–2
c f (x) = sin x + cos x ✓ ✓ p ⇡◆ p ⇡◆ = 2 cos x = 2 sin x + 4 4
171 140
c
1 b 1 2 1 b 0 5, 1 b 9, 1 p p 1 4 5 8 5 b c 9 p 9 81 2 3 b sin(x + y) + sin(x y) ⇡ 7⇡ 11⇡ 0, , 2⇡ b , c 0, ⇡, 2⇡ 2 6 6 ⇡ 3⇡ ⇡ ⇡ 7⇡ 4⇡ , e , , , 2 2 6 3 6 3 7⇡ 3⇡ 19⇡ 7⇡ , , , 12 4 12 4 2 y = 2 cos x y
2
y
√2 1
5π 4
0
π 4
–√2
3π π 4
0 x
2π
p
y
0
π 3
5π 6
4π 3 π
11π 6 2π
π
2π 3
2π
0 –1
d f
b 4, 2 c 4, 4 d 2, 0
−π 2
−π
1 3 ⇡ 5⇡ 7⇡ 11⇡ ⇡ 5⇡ 13⇡ 17⇡ , , , b , , , 6 6 6 6 12 12 12 12 ⇡ 11⇡ 13⇡ 23⇡ 25⇡ 35⇡ , , , , , 18 18 18 18 18 18 ⇡ 3⇡ 5⇡ 7⇡ ⇡ 5⇡ 7⇡ 11⇡ , , , e , , , 4 4 4 4 6 6 6 6 3⇡ 7⇡ 11⇡ 15⇡ ⇡ 7⇡ 11⇡ , , , g , , 8 8 8 8 2 6 6
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x
4π
1
Technology-free questions
c
10π 3
y
Chapter 14 review
3 a
x◆ 2
2π
c f (x) = tan(2x)
x
−√3 −2
2 a 5, 1
x 3π 2
3
2 1
π 2
✓⇡ 2 sin 2
b y=1
✓ 5⇡ ◆ 3 cos x = 2 cos x 6 ✓ ✓ 5⇡ ◆ ⇡◆ = 2 sin x + = 2 sin x 3 3
d f (x) = sin x
y
7π 4
e 1,
15
2 9
16 a
p 85 cos(✓ p
0 −1
π 2
π
3π 2
↵) where ↵ = cos
2π
1
x
✓ 2 ◆ p 85
2 ii p 85 ✓ 2 ◆ ✓ 1 ◆ 1 iii ✓ = cos p + cos 1 p 85 85
b i
85
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 725 c 4A 9A
y
5 C 10 D
4
x
0
d
15A
Extended-response questions ✓ 2 ◆ p 1 b P = 10 5 cos(✓ ↵) where ↵ = cos 1 p ; 5 ✓ = 70.88 c k = 25 d ✓ = 45 2 a AD = p cos ✓ + 2 sin ✓ b AD = 5 ✓cos(✓◆ ↵) where 1 ↵ = cos 1 p ⇡ 63 5 p c max length of AD is 5 m when ✓ = 63 d ✓ = 79.38 3 b ii a p = 1, p b=1 p p 1+ 2 3 2 2 3 1 c p = p p 3 1 1+ 3+ 6 p p p = 6+ 2 3 2 4 a i h1 = cos ✓ ii h2 = cos ✓ sin ✓ iii h3 = sin2 ✓ cos ✓ iv hn = sinn 1 ✓ cos ✓ for n 2 N c 19.47 ✓ ◆ ⇡ 5 a ii 2 cos ✓5⇡ ◆ ✓⇡◆ b iii 4 cos2 2 cos 1=0 5 p 5 1+ 5 iv 4 2 1 6b or 3 2
y
–1
0 –1
e
Answers
Multiple-choice questions 1 A 2A 3 B 6 E 7C 8 E
x
1
y 4
0
–2
f
2
x
y
0
Chapter 15
x
2
Exercise 15A 1 a
y
g
y
3
0
−3
b
x
y
–1
3
0
h
x
y 4
1 -1
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
0
1
x
–3
0 1
x
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
15A
726 Answers i
f
y
y 0
(
Answers
2 a
x
0
-1
g
y
2
1 π 2
b
x
3π 2
)
(3π2 , 3) (π2 , 1)
(2π, 2)
(3π2 , 13 ) (2π, 12)
0
h
y
x
2π
2π
5
(−π, 5)
π
x
π
y
0
(−π, 15)
(π, 5)
(π, 15 )
1 0
−π
c
x
(π, −3)
y
0 −1
2π
π, − 1 3
−1
π
x
3 a ( 1, 1) b
y
2 1 0 −π
π
4 a d
x
−1
x
1
y
y
1 0 1
x
2 0
x
π
2π
3π
4π
b e
5
y
−2π
−π
0
π
2π
✓ 5 ± 3p5 10
y
x 0
◆ ✓ 5 ± p5 ◆ , 1, ,1 10
(π2 , 2)
(3π2 , 2)
(π2 , 21)
(3π2 , 12) π
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
2π
x
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 727
Answers
6
Exercise 15C
y
x2 12 x2 y= 1 12 y2 x= 1 12 ✓1 ◆ 2 y a x= b ,0 4c 12 1 a y= (x2 2ax + a2 + b2 2b 2c 1 2 b y= (x 2x 4) 2 y = 1 or y = 19 p p (2, 1 + 3) or (2, 1 3)
1 y= 1 0
2
x 1
3
(–k, 1 – k2)
4 5
6 7
x
15B ! 15D
7 a f (x) = (x + k)2 + 1 k2 b i 1 < k < 1 ii k = ±1 iii k > 1 or k < 1 c i
c2 )
Exercise 15D
ii
1 a
y 8
(–k, 0)
x –3
x
3
iii –8
x
y
b 5
(–k, 1 – k2) –10
x
10 –5
Exercise 15B
c
1 (x 1)2 + (y + 2)2 = 42 2 (x + 4)2 + (y 3)2 = 52 3 a y= x x 3 4 a y= + 2 4 5 (0, 3) or (3, 0) ✓9 3◆ 6 , 10 10 ✓ 72 154 ◆ 7 (6, 8) or , 17 17 8 a 2y x = 1 b x + y = 2 d (x 1)2 + (y 1)2 = 52 9 y = 2x + 1 10 y = 6 11 a The lines x = 0 and y = 0 ✓ 1 ◆2 ✓ 1 ◆2 1 b x + y = 2 2 2 12 (x 4)2 + y2 = 4 13 The lines y = 1 and y = 5 14 3
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
y 5 3
–3
x
–5 y
d
3
–8
c P(1, 1)
x
8 –3
2 a
b
y
y -24 5
4
-6 5
x
(3, 4) (-3, -4)
3
-4
x
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
15E
728 Answers c
d
y
d
y
y
(5, 5) y=
Answers
3 3
(2, 3)
4 – Ö7 2
3
4 5 6 7
(5, 0) (2, 0) x
4 + Ö7 2
(8, 0)
5x 3
x
x
3
–3
y=–
(5, –5)
x2 y2 (x 2)2 y2 a + =1 b + =1 25 16 9 4 2 (x + 1) c + (y 1)2 = 1 4 x 2 y2 + =1 4 3 x 2 y2 + =1 5 9 (x 4)2 y2 + =1 16 12 x 2 y2 + =1 25 9
2 a
5x 3
y y=x–3 x 1 – Ö5
1 +Ö5 –2
(1, –2) y = –x – 1
b
y –3
y = 2x + 4
(–1, 2) –1 – √5
–1 + √5
x
Exercise 15E 1 a
y y=
3x 2
y = –2x
c 2
–2
y 3 + 3√5
x
y = 3x – 3
(2, 3)
y=–
b
3x 2
x
2 3 – 3√ 5
y = 3x + 9
y y = 2x
d
1
–1
y 5 y = (x – 4) 3
5√7 3
x
(4, 0) 1
y = –2x
c
–
y
5
e y=
x 2
y=– –5
5√7 3
x 2
x
7 5 y = – (x – 4) 3
y
y=
x 2 – 2√5
(2, –1)
x –2 2 2 + 2√5
y=–
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x
x 2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 729 5 a y = 2x2 where 1 x 1 y b
y
y=
3
Answers
f
3x 5
x
(5, 3) x 5 + 5√2
5 – 5√2
4 5 6
3x +6 5
(1, –2)
(–1, –2)
✓ 3 4◆ ✓3 4◆ , , , 5 5 5 5 2 7 a y = 2x + 1 b 1 x 1 y d
x 2 y2 =1 9 7 5x2 4y2 = 20 (x + 3)2 y2 =1 16 48 2 2 (y + 5) x =1 4 12
6
(–1, 3)
c 1y3
15F
3
y=–
(1, 3)
Exercise 15F 1 a y = x2 + 2x
b
x
y 2
8 a y= x +1 y d
t=2
(0, 1)
t=0
b y = 2(x + 1)2 + 1
1
y
y
( 12 , 0 (
x 2
9 y = 1 + 2x where 1 x 1 y
(0, 3) x
(0, –1)
c y>1
x
t=1
2 a y = 2x
b x>0
(–1, 1)
(1, 1)
√2 2
√2 2
(–1, 1) x
c y = x3
d y=
y
–
1 x
1
x
–1
y
10 b
y
(1, 1) x
x (2, 0)
(0, –1)
x
x=1
3 a x2 + y2 = 22 (x + 1)2 (y 2)2 b + =1 32 22 c x = 3 cos t 3 and y = 3 sin t + 2 (other answers are possible) d x = 3 cos t 2 and y = 2 sin t + 1 (other answers are possible) 4 x = t and y = 3t + 1 (other answers are possible)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
11 a
2t t2 + 1 2 y= 2 t +1
c x=
y 2
(0, 1) x
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Answers
15G ! 15I
730 Answers 12
✓ ⇡◆ ✓ ⇡ ◆ ✓ p 3⇡ ◆ 4⇡ ◆ , 2, b 2, , 2, 4 4 3 3 ✓ p ⇡ ◆ ✓ p 3⇡ ◆ c 2 2, , 2 2, 4 4 ✓ ◆ ✓ 3⇡ ⇡◆ d 2, , 2, e (3, 0), ( 3, ⇡) 4 4 ✓ ◆ ✓ ◆ ⇡ ⇡ f 2, , 2, 2 2 p 3 7 p 4 PQ = (r1 )2 + (r2 )2 2r1 r2 cos(✓2 ✓1 )
y
t=5
2 a
t=1
t=2
t=6
t=0
t=3
x
t=4
Exercise 15G 1 a (0, 1)
b(
2,
Exercise 15H
p p 2, 2)
y
✓p
y
1 2
y A 1,
p 2
B
1
1
3p 4
2
0 x
x
–2
–1
0
1
x
2
–1
c (0, 3)
d(
p p 2, 2) y
y
x
–2
x
D
e (1, 0)
f (0, 0) y
y
p
E –1
1
4 cos ✓ c r = tan ✓ sec ✓ 1 e r2 = cos(2✓) 3 a x=2 c y=x 4 a (x 3)2 + y2 = 9 c (x + 3)2 + y2 = 9 5 (x a)2 + y2 = a2
x
F
p g ( 2 3, 2)
h (1,
b r=
a sin ✓
x
y
x
4 5p – 4
e = 0.7
2p 3
2
x
e = 0.8
–2 H
p p i ( 2, 2)
e = 0.9
y
b Ellipse becomes larger and narrower –2
2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b d b d
y
p 3)
y
I
f
Exercise 15I 1 a
G
d
6 a Equation x = a x
1 cos ✓ sin ✓ r = 3 or r = 3 5 r= 2 cos ✓ 3 sin ✓ x2 + y2 = 22 3x 2y = 4 x2 + (y 2)2 = 4 x2 + (y + 4)2 = 16
b r2 =
2 a r= 2 p 4
p − 2
3 C
–2
–
p 4
x
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 731 b
y
(1, p)
0, p 2
(1, 0)
y
x
2
x
c
y
2 – 1 2 (1, 0)
d
2p
y
y
)
(
1,
p 6
)
(2p, 2)
(3p2 , 1)
2
(p2 , 13) x
(2p, 12) x
0
p
2p
x 3 3 (x 3)2 + (y 2)2 = 62 p 4 C( 2, 4), r = 20 2 y=
(1, 3p2 ) 4 a
y 7p –1, 4
(
3p 2
(p2 , 3)
b
(
x
p 2
x
(–1, p3) 5p 6
15 review
y
(1, 2p3 )
1,
1 2
(–1, 1)
2,3p 2
3 a
Answers
2 a
)
(1, p4)
4
1
5 a 2 –3
x 3
y
3
x
2 –2
(–1, 3p4 )
(1, 5p4 ) 5 a
b
y (2, 2)
y 2–
Ö2
–Ö2
b (x2 + y2 )2 = 2x2
x
4Ö2 3
(0, –1)
2+
(2, –1)
4Ö2 3
x
(4, –1)
2y2 (2, –4)
Chapter 15 review
6 C( 2, 0); Intercepts (0, 0), ( 4, 0)
Technology-free questions 1 a
7 a
y
y
y = 2x
y = –2x
–2
2
–1 x
1
x
–1 2 –2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
16A
732 Answers b
c 20 metres
y
e
1 + 4Ö2 y = 2x + 5 (1, –2)
8
(y
ball 1 10
5)2 =1 12
4 9 a y = 4 2x (x 1)2 (y + 1)2 c + 32 52 2 d y = 1 3x where 10 a y = 2(x + 1)2 1 c 1y7 d y
6 a
=1
20
30
√2
1
0
b
60
x
2
3
5
4
y
√2 1
0
p p 11 ( 2, 2) ✓ ⇡◆ ✓ 2⇡ ◆ 12 4, , 4, 3 3 5 13 r = 2 cos ✓ + 3 sin ✓ 14 x2 + (y 3)2 = 9
1
p 1 (2⇡ + ⇡ 2) 2
c
(–1, 1)
1 x 1
Distance = d Area =
2
3
4
p ⇡ (a + a2 + b2 + b) 2
⇡ 2 (a + b2 ) + ab 2
Chapter 16
Multiple-choice questions 1 B 2A 3 D 6 D 7C 8 C
Exercise 16A 4C 9E
5 D 10 B
Extended-response questions 9 1 a y = 2x 2 b (x 8)2 + (y + 1)2 = 20 x2 x2 (y 6)2 2 a y= +1 b + =1 12 12 16 (y + 4)2 x2 c =1 16 48 1 3 a y= x(40 x) 20 b y (20, 20)
10 0
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
50
x 1
x
20
40
y
1
0
ball 2
(30, 15)
1
1x1 b 1x1
(1, 7)
20
(40, 20)
f (30, 15) g Yes (same position at same time) 4 c (x 4)2 + (y 7)2 = 25
b x2 + y2 = 22
(0, 1)
60)
0
1 – 4Ö2
2)2
(20, 20)
10
y = –2x – 3
(x
20)(x
y 20
x
1 (x 20
d y=
30
40
x
1 a b c d e f
Re(z) Im(z) 2 3 4 5 1 3 2 2 4 0 3p p0 2 2 2
2 a a = 2, b = 2 b a = 3, b = 2 or a = 2, b = 3 2 1 c a = 5, b = 0 d a= , b= 3 3 3 a 6 8ip b 6 i c 6 2i d 7 3 2i e 2 3i f 4 + 2i g 6 4i h 4 + 6i i 1 + 11i j 1 p 4 a 4i b 6i c 2i d i e 1 f 1 g 2 h 12 i 4 5 a 1p + 2i b 3p+ 4i c 2 2i d 6 3i
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 733 b z1
5 6
7 8
15 + 8i b 2i e 2 + 5i p 5 + 2i 2+i b 4 7i e 1 i h 2 + 4i b 8 16i e 1 g (1 + 2i) h 10 1 17 a= , b= 29 29 7 6 a i b 17 17 1 1 d i e 2 2 5 3 a= , b= 2 2 42 84i a + 5 5 1 c (4 + i) 17 e 2 2i
8i 5 b 1 d 5i 3 2i 4 7i 1 i 20 8i 4
c 2 + 16i f 4 + 19i 3i c f
−3
4 + 7i 1+i
c 4 f8
9i
0
6
z1
−5
2i
z1 − z2
−9
4 7 1 c i 2 2 3 1 f + i 20 20
i 2 3 + i 13 13
Im(z) 6
c (−8 + 6i)
e 0 d (−1 − 3i)
5 c (−2 + 5i)
D=2 2
B = 2i,
d
C= 3
4i
F= 1
i
Im(z) 1
−2
f
1
2
3
−4
3 a z1 + z2 = 3
4 Re(z)
−5
a, e (2 − 5i)
p c ± 5i d 2 ± 4i p p 1 e 1 ± 7i f 1 ± 2i g ( 3 ± 3i) 2 p p 1 1 h ( 5 ± 7i) i (1 ± 23i) 4 6 p p 1 j 1 ± 2i k (3 ± 11i) l 3 ± 5i 2
1 a ±2i
4
3 z1 + z2
6
z1
Re(z)
b ±3i
Exercise 16E ✓⇡◆ 1 a 2 cis 3 ✓ 5⇡ ◆ c 4 cis 6 ✓ ⇡◆ e 24 cis 3 2 a 3i
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
5 Re(z)
Exercise 16D
a
i
−5
2
e
Im(z)
−3 −2 −1 0 −1
0 −2
d (−5 − 2i)
−3
z2
b (5 + 2i)
−2 −5
c
−5 −4 −3 −2 −1 0 −1
Re(z) b (1 − 3i)
−3
2
2i, E = 3,
b
1
3 1 − i 10 10
Im(z) 5
Exercise 16C 1 A = 3 + i,
a (1 + 3i)
3
−8
1 b (1 i) 2 1 d (6 + 43i) 130
Re(z)
9
16B ! 16E
1 a d 2 a c 3 a d g 4 a d
z2 = 9
z2 Im(z) 4
Answers
Exercise 16B
✓ ⇡◆ p 2 cis 4 ✓ 3⇡ ◆ p d 4 2 cis 4 ✓ 3⇡ ◆ 1 f p cis 4 2 p p p 1 2 b p (1 + 3i) = (1 + 3i) 2 2 b
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
16 review
734 Answers c e g 3 a c e g i
p
5 3 + i d p (1 2 p 6( 3 i) p 5 (1 + 3i) 2 p 3 2(1 + i) p 5 (1 3i) 2 p p18(1 + 3i) 3+i p 4(1 3i)
p 5 2 (1 i) 2 3(1 i) p 5 (1 + 3i) 2 p 6(1 + 3i) p 18(1 + 3i) p 3(1 + i) 4 5 2
i) = f h b d f h j
6
✓ 2⇡ ◆ a z2 = cis 3 ✓ ⇡◆ 1 c = cis z 3
Im(z)
(3p4 )
iz = cis
Re(z)
0
( )
p 1 z = z = iz = cis – 4
Chapter 16 review Technology-free questions 1 a (2m + 3p) + (2n + 3q)i b p qi c (mp + nq) + (np mq)i (mp + nq) + (np mq)i e 2m d p2 + q2 f (m2 n2 p2 + q2 ) + (2mn 2pq)i m ni (mp + nq) + (mp nq)i g 2 h m + n2 m2 + n2 3 (mp + nq) + (np mq)i i p2 + q2 2
Im(z) 2 c −8
−6
−4
−2 b
a d 3 a c e 4 a c e
p
d
z2 = cis
(2p3 )
0 f 2 a −2
✓ 3⇡ ◆
✓ ⇡◆ b z = cis 4 ✓ ⇡◆ d iz = cis 4
4 ✓ ⇡◆ 1 c = cis z 4
Multiple-choice questions 1 C 2 D 3C 6 E 7 D 8D
4 D 9 B
5D 10 D
Extended-response questions p p 1 a z = 3 + i or z = 3 i b i Im(z) z = √3 + i
1
4 Re(z)
0
−4
Im(z)
Re(z)
0
( )
p 1 z = z = cis – 3
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
a iz = cis
e
p 1 3i b 2 2 3i c 8 p p p 1 1 (1 + 3i) e 1 + 3i f (1 3i) 4 4 ✓ ◆ ✓ ◆ p ⇡ ⇡ 2 cis b 2 cis 4 3 ✓ ✓ p3 ◆◆ ✓⇡◆ p 1 13 cis tan d 6 cis 6 4 ✓ 3⇡ ◆ ✓ ⇡◆ 6 cis f 2 cis 4 6 p p p 3 2 3 2 1 3i b + i 2 2 p p p p 3 2 3 2 3 2 3 2 + i d + i 2p 2 2 2 3 3 3 i f1 i 2 2
5
✓ ⇡◆ b z = cis 3 ✓ 2⇡ ◆ d cis 3
√3
-1
Re(z) z = √3 - i
ii x2 + y2 = 4 p 2 a i 6 2 ii 6 3 a Im(z)
iii a = 2 b Z
O
p 2+1
P
A
Re(z)
Q
✓✓◆ p 6 a |z + 1| = 2 + 2 cos ✓ = 2 cos , 2 ✓ Arg(z + 1) = 2 ✓✓◆ p b |z 1| = 2 2 cos ✓ = 2 sin , 2 ⇡+✓ Arg(z 1) = 2 ✓✓◆ ✓z 1◆ ⇡ z 1 c = tan , Arg = z+1 2 z+1 2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 735 c
( p2 , 2 ( p 3i)
0
b
2+i e 2+i f g 5 13 i i j3 i k 34 6 a (z 7i)(z + 7i) b (z 1 3i)(z 1 + 3i) ✓ 1 2 ◆✓ 1 2 ◆ c 9z i z + i 3 3 3 3 ✓ ◆✓ 3 3 ◆ d 4 z+ i z+ +i 2 2 7 a 2 + i, 2 i b z= 1 8 a y
2p
p 2 3 d 3
x
y (2 p, 3)
3 (p, 1)
(2 p , 13 ( 2p
0
9 a
x
y 5
d 10 h 24i 8 i 4 7i d 13 8+i 2 i h 5 1 3i l 3 4i 2
c
1+i
p 2
p
1 3
Technology-free questions p 5 4 3 1 a b c 4 3 3 p 6 2 ± 3 4 a 6 b 4i c 13 e 36 f 16 g 24i 5i
p 2
17 revision
d
(2 p, 1)
( p2 , 12 (
1
Chapter 17
5 a 3
y
Answers
7 a = b2 4ac b b2 < 4ac p b 4ac b2 c i , ii 1 a 2a 2ac p 1 1 8 a z1 = ( 1 + 3i), z2 = ( 1 2 2 2⇡ c |z1 | = 1, Arg(z1 ) = ; 3 2⇡ |z2 | = 1, Arg(z2 ) = 3 p 3 d 4
4
–4
x
–5
b
y 4 + 3Ö3 2 (–1, 2) –3 + 2Ö5 3 –3 – 2Ö5 3
i or z = i
x
4 – 3Ö3 2
10 a
y y = 3x
2 1 2 –2
–1
0
–1
x
b
y
y –1 + 4Ö2
2 1 2
x
y = –3x
(–32 , –4( b
1
(2, –1)
(1, 1)
C¢
y = 2x –5 x y = –2x +3
–1 – 4Ö2
x
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
17 revision
736 Answers 11 2x + 4y = 17 (x 1)2 (y 1)2 12 + =1 4 3 2 x 13 y = 1 8 14 a 3x + 2y = 7 b x 2 + y2 = 1 (x 2)2 (y 3)2 c + =1 4 9 2 2 y x d =1 9 4 15 a y = 1 2(x + 1)2 b 1x1 c 7y1 d
2 a i 5m b y (3, 8)
(24, 5)
(9, 2)
3
x
–1
5 (1, –7)
6
p 16 ( 3, 1) ✓ p ⇡ ◆ ✓ p 3⇡ ◆ 17 2 2, , 2 2, 4 4 p 18 a x2 + y2 = 52 b y = 3x d 3y + 4x = 2 e y = 19 a
(21, 2) x
Ö2 – 2 2
(15, 8)
(0, 5)
y
(–1, 1)
ii 8 m
7 c y=3
1 2x
8
y
9
4
c i 8m ii 2 m d i 0, 6, 12, 18, 24 ii 0.65, 5.35, 12.65, 17.35 ⇡ 5⇡ ii cm a i 6 3 b 19.78 cm c i 14.62 cm2 ii 11.25 cm2 iii a 155 m b i 16.00 m ii 29.04 m iii c 32.7 cm2 a 12:05 p.m. b 2752 km r 2 2 p q pq a x= + cos ✓ 4 4 2 r p2 p2 pq b y= + + cos ✓ 4 4 2 p d 31 cm b i 51.48 cm ii 4764.95 cm2 iii 94.80% r 2581 c i ⇡ 9.12 cm ii 31
10 a i
y
(p2 , 3)
(0, 2)
x
Multiple-choice questions 1 B 2 B 3 D 4 E 7 D 8 C 9 E 10 A 13 A 14 A 15 C 16 E 19 B 20 C 21 C 22 B 25 A 26 C 27 C 28 A 31 C 32 A 33 B 34 B 37 B 38 D 39 A 40 E
0
D D E D C B D
6 12 18 24 30 36 42
A E C E E C A
Extended-response questions 1 a i \BCA = 138.19 , \ABC = 11.81 ii \BC 0 A = 41.81 , \ABC 0 = 108.19 b i 24.56 ii 114.00 iii 89.44 c i 1788.85 ii 3027.87 iii 1239.01
7p 6
(p2 , 13)
1
5 11 17 23 29 35 41
x=
ii
17 c 26.1
43.18 cm2
x=
11p 6
(2p, 1)
p 3p , –1 2
( y
288.29 cm2
2p
)
x
(π2 , 5) (2π, 3)
(0, 3)
( ) ( 0, 1 3
0
π, 1 2 5
( ) 3π , 1 2
) π
(2π, 31) 2π
x
b k=2
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 737 y
p, 4 2
( )
c i✓ ii ⇡ ✓ iii ✓ iv (⇡ ✓) sin ✓ v (⇡ ✓) cos ✓ d x = cos ✓ (⇡ ✓) sin ✓ and y = sin ✓ + (⇡ ✓) cos ✓
3p x= 2 (2p, 2)
(p2 , 14)
(2p, 12)
Chapter 18
x
0
p
2p
8 p 5
12 m 2m
10 m 2m 2
b 110⇡ m8 3⇡x2 > > > 6⇡x + 110⇡, > > < 4 c A(x) = > > > ⇡x2 > > : 5⇡x + 109⇡, 2 d A (2, 101p)
110p
0x2 2 p or k < 5 13 a
Answers
c
x 1
2
3
4
"
# " # " # 4 2 13 1 X+Y= 2X = 4Y + X = 2 4 2 " # " # 2 3 3 X Y= 3A = 2 6 9 " # 1 3 3A + B = 7 7
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Answers
18C ! 18D
738 Answers 2 2A =
"
6A =
2 0 "
6 0
3 a Yes " # 6 4 4 a 4 4 " # 6 5 c 8 1 " # 0 1 5 a 2 3
# 2 4
3A = #
6 12 b Yes
"
3 0
3 6
#
# 0 9 12 3 " # 6 13 d 16 7 " # " # 3 3 2 3 b c 6 3 1 7 2 3 666 9 23 777 " # 666 7 2 4 666 2 2 77777 6 X= , Y = 66 777 666 1 0 3 7 4 11 75 2 " # 310 180 220 90 7 X+Y= 200 0 125 0 represents the total production at two factories in two successive weeks
Exercise 18C
b
"
" # " # " # 4 4 5 1 AX = BX = AY = 5 1 8 " # " # 2 0 1 IX = AC = 1 1 2 2 3 " # 66 177 1 1 CA = (AC)X = 664 775 0 1 0 " # " # 9 1 2 C(BX) = AI = 5 1 3 " # " # 3 2 1 0 IB = AB = 1 1 0 1 " # " # 1 0 3 8 2 BA = A = 0 1 4 11 " # " # 11 8 1 3 2 B = A(CA) = 4 3 1 4 " # 2 5 2 A C= 3 7 2 Defined: AY, CI; Not defined: YA, XY, X2 , XI " # 0 0 3 AB = 0 0 4 No " # 1 1 5 One possible answer is A = 1 1 " # h i 4 2 6 LX = 7 , XL = 6 3 7 AB" and BA # are not defined unless m = n 1 0 8b 0 1 9 One "possible # answer" is # 1 2 2 1 A= , B= 3 4 1.5 0.5
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
10 One "possible # answer" is # " # 1 2 0 1 1 2 A= , B= , C= , 4 3 2 3 2 1 " # " # 1 11 1 11 A(B + C) = , AB + AC = , 4 24 4 24 " # 11 7 (B + C)A = 16 12 " # " # 1 1 2 3 11 For example: A = and B = 1 1 4 5 " # 29 12 a , John took 29 minutes to eat food 8.50 costing $8.50 " # 29 22 12 b , 8.50 8.00 3.00 John’s friends took 22 and 12 minutes to eat food costing $8.00 and $3.00 respectively " # " # 3 4 7 24 13 A2 = , A4 = , 4 3 24 7 " # 527 336 A8 = 336 527 " # " # " # 1 2 1 3 1 4 14 A2 = , A3 = , A4 = , 0 1 0 1 0 1 " # 1 n An = 0 1
Exercise 18D 1 a 1
2 a
"
b 1 4
1 3
"
2 3
3 0777 7 1 77777 5 k 21 66 4 a A 1 = 664 2 0 " 5 b AB = 3 1
B 1A
1
2 666 1 6 5 a 66666 2 4 1 2 666 5 666 6 2 c 6666 666 11 4 2
#
c 2
2 66 = 664 2 66 = 6664
3 3 777 77 2 7777 5 2 3 7 777 7 2 77777 7 21 7777 5 2
d
1 2
"
0 1
#
2 3
2 3 666 2 1 777 666 7 6 7 14 77777 b 6666 7 666 1 3 7777 4 5 7 14 " # cos ✓ sin ✓ d sin ✓ cos ✓
#
2 6661 6 c 66666 40
c A 1B
2 2
13 77 27 7
"
1
1 3
# 2 2
5, B = 2 1 3 # 17 66 1 27 777 , (AB) 1 = 6664 23 55 1 2 2 13 77 1 27 57, 3 1 3 1 17 2 27 777, (AB) 1 = B 1 A 1 3 55 1
2
2
b
"
0 1
7 8
#
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Answers 739
7
10
Exercise 18E 1 a
"
#
3 10
2 a x=
# 5 17 1 10 , y= 7 7 b
"
b x = 4, y = 1.5
3 (2, 1) 4 book $12, CD $18 " #" # " # 2 3 x 3 5 a = 4 6 y 6 " # 2 3 b is non-invertible 4 6 c System has solutions (not a unique solution) d Solution set contains infinitely many pairs 6 a A 1C b B 1A 1C c A 1 CB 1 d A 1 C B e A 1 (C B) f (A B)A 1 = I BA 1
Chapter 18 review Technology-free questions " # " # 0 0 0 0 1 a b 12 8 8 8 2 3 666 a 777 6 7 2 66666 3 77777, a 2 R a5 42 4 3 a Exist: AC, CD, BE; Does not " exist:# AB h i 1 1 2 1 b DA = 14 0 , A = 1 7 3 " # " # 2 0 2 1 4 AB = , C 1= 3 1 2 2 2 2 " # 1 2 5 3 5
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
7 8
3 0777 7 077777, 5 4
0 4 0
1
# " 3 5 1 ii 5 8 18 b x = 2, y = 1
8 a i
"
A
21 666 2 66 = 6666 0 64 0 18 19
Multiple-choice questions 1 B 2 E 3C 6 A 7 E 8A
#
0 0 1 2
iii
4 E 9 E
1 7
3 077 77 17 77 27 775 0 "
3 1
1 2
#
5C 10 D
Extended-response questions " #" # " # 2 3 x 3 1 a i = 4 1 y 5 " # 1 1 3 1 ii det(A) = 14, A = 14 4 2 " # 1 9 iii 7 1 ! 9 1 iv , is the point of intersection of 7 7 "the two# "lines # " # 2 1 x 3 b i = 4 2 y 8 ii det(A) = 0, so A is non-invertible c Equations of two parallel lines 2 3 " # 6660.2777 6 7 79 78 80 2 a b 666660.377777 80 78 82 4 5 0.5 c Semester 1: 79.2; Semester 2: 80.4 d Semester 1: 83.8; Semester 2: 75.2 e No, total score is 318.6 f 3 marks 2 3 2777 66610 " # 666 7 47777 70 6 8 777 3 a 6666 b 666 8 8777 60 4 5 6 10 c Term 1: $820; Term 2: $800; Term 3: $1040; Term 4: $1020 2 3 2 3 6662 2 1777 66660777 66662 2 17777 6 7 7777 d 6666 e 666665577777 6663 4 2777 4 5 40 4 5 3 4 2 f Term 1: $270; Term 2: $270; Term 3: $480; Term 4: $480 g Term 1: $1090; Term 2: $1070; Term 3: $1520; Term 4: $1500
18E ! 19A
9
2 6664 6 6 A2 = 666660 4 0
Answers
6
2 3 2 3 666 3 11 777 666 11 17 777 666 777 666 7 6 8 666 16 8 777 16 77777 a 6666 b 7 6 7 666 1 6666 1 7 7777 3 7777 4 5 4 5 16 16 4 4 2 3 666 1 7 666 0 77777 777 6666 a11 7 666 1 7777 64 0 5 a22 " # " # 1 0 1 0 , , 0 1 0 1 " # " # " # " # 1 0 1 0 1 k 1 k , , , , k 2 R, k 1 k 1 0 1 0 1 2 3 666 a b 777 666 777, b , 0 2 7 64 1 a a5 bp a=± 2
Chapter 19 Exercise 19A 1 a ( 2, 6) c (26, 2) 2 a (3, 2)
b ( 4, 9)
b ( 8, 22) d ( 4, 2) c (8, 3) d (7, 11)
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Answers
19B
740 Answers # " # 2 3 11 3 b 4 5 3 8 " # " # 2 0 0 1 c d 1 3 1 0 4 Unit square is blue; image is red 3 a
"
a
y (1, 1)
1 0 0
1
b
3 2 "
1 8 a 1 " 1 b 1 " 1 c 1
1 a i
(1, –1)
–1
"
#" # " 1 2 = 1 3 # " 1 1 or 2 2 # " 2 or 1 # " 2 or 3
3 1
#
1 1
2 1 2 3
#
# 1 1 # 1 1
Exercise 19B
x
2
7
"
1 0
0 2
#
y
ii 2
y 4
1 (2, 3)
3
0 0
2
b i
(1, 1)
1 0 0
1
x
2
"
3 0
0 1
#
1
2
1
2
x
y
ii 2 1
c
y
0
2
0
(1, 2)
c i
(1, 1)
1 0 0
1
"
1 0
3 1
#
y
ii 1 0
x
2
0 1
y 3 (–1, 2)
d i
2 (1, 1)
1
–1
0
1
2
–1
1 1
0 1
#
x
3
y
ii 1 0
3 (3, –1)
0 1
x
x
–1
e i
y
5
"
(2, 1)
0
"
1 0
0 1
#
ii
y 1
5
0
4
–1
0 1
3
f i
2
"
0 1
# 1 0
ii
x
y 1
1 0
x 0
3 6 4
2
–1
d
"
x
3
5 6
#"
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
1
2
3
# " # 2 14 = 4 16
0 0
1 –1
1
x
–1 1
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 741
ii
" 0# " # " # " # x x 2 x+2 = + = y0 y 0 y
Exercise 19C
y
1 a
1 0 1
0
2
x
3
c
–1
ii
" 0# " # " # " # x x 0 x + = 0 = y y 3 y 3
2 a
y 0
x
1
0
3 a
–1 –2
c
–3
c i ii
" 0# " # " # " x x 2 x = + = y0 y 4 y
2 4
#
4 a
y 0 –1
–2
0
x
c
–1 –2 –3
5 a
–4
" 0# " # " # " # x x 0 x d i 0 = + = y y 2 y+2 ii
6 a
y
b
3
#
19C ! 19D
b i
2p 3 666 3 1 777 666 777 0 1 6 2 p2 7777 b 6666 666 1 1 0 3 7777 4 5 2 2 p 3 3 2 2 1 7 666 1 666 1 3 777 666 777 66 p p 77777 6 666 p 6 2 2 777 2 777 d 6666 2 666 777 777 6 1 1 3 1 664 775 664 7 p p 75 2 2 2 2 ✓ 5p2 p2 ◆ ( 3, 2) b , 2 2 p 3 2 666 1 3 777 " # 6666 2 7777 0 1 2 777 b 6666 p 1 0 1 7777 6664 3 5 2 2 p 3 2 2p 3 666 1 666 3 3 777 1 777 666 7 7 6666 2 666 p 2 2 77777 2 77777 p d 6666 666 777 7 1 77 3 7777 664 3 6664 1 5 5 2 2 2 2 2 3 2 3 666 4 3 777 666 12 5 777 666 777 666 7 666 5 5 777 6 13 13 77777 b 6666 666 777 7 666 5 12 7777 664 3 4 775 4 5 5 5 13 13 2 3 2 3 666 5 666 4 12 777 3 777 666 7 7 6666 5 666 13 13 77777 5 77777 d 6666 666 777 7 666 3 5 77 4 7777 664 12 5 4 5 13 13 5 5 2 3 666 1 m2 2m 777 666 2 7 ✓ 23 47 ◆ 666 m + 1 m2 + 1 77777 b , 666 777 2 m 1 77 37 37 664 2m 5 m2 + 1 m2 + 1 p 3 2p 666 2 2 777 6666 2 777 666 p p2 7777 666 2 2 7777 64 5 2 2 p y c 2 1 "
Answers
2 a i
2 1
1 0 0
1
2
x
" 0# " # " # " # x x 1 x 1 e i 0 = + = y y 2 y+2 ii
0 0
✓ 1 p3 ◆ ✓ 1 p3 ◆ , ,B , 2 2 2 2 b equilateral p p c y= 3x, y = 0, y = 3x
3
Exercise 19D
2 1
1
0
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
–1
x
7 aC
y
–2
1
0
x
"
1 0
0 3
#
2
"
0 1
1 0
#
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
19E ! 19G
742 Answers # 1 0 0 1 " # " # cos 180 sin 180 1 0 b = sin 180 cos 180 0 1 " # " # 2 0 2 0 a b c No 0 1 0 1 " # " # 1 0 1 0 a b c Yes 0 1 0 1 a (x, y) ! ( x 3, y + 5) b (x, y) ! ( x + 3, y + 5) c Yes " #" # " #" # 1 0 1 0 2 0 1 0 a b 0 1 0 1 0 3 0 1 " #" # " #" # 1 0 0 1 2 0 0 1 c d 0 2 1 0 0 1 1 0 " # 0 1 a 1 0 " # " # cos 90 sin 90 0 1 b = sin 90 cos 90 1 0 ✓ = 180 k, where k 2 Z a "2✓ # cos2 ✓ sin2 ✓ 2 sin ✓ cos ✓ b 2 sin ✓ cos ✓ cos2 ✓ sin2 ✓ 2 c cos(2✓) = cos ✓ sin2 ✓
3 a
4 5 6 7
8
9 10
"
sin(2✓) = 2 sin ✓ cos ✓ 11 a x0 = y + 1
b
" # 2 1
y0 = x + 2 p 3 p 3 2 2 p 666 1 666 2 3 777 2 777 777 666 777 6666 2 7 6 2 77 666 p2 p2 7777 12 a 6666 p b 7 666 2 666 3 1 7777 2 7777 64 4 5 5 2 2 2 2 p p p 3 2p 666 2 + 6 2 6 777 777 6666 4 4 p p p 7777 c 6666 p 666 6 2 6 + 2 7777 4 5 4 p p2 p p 2+ 6 6 2 d cos 15 = , sin 15 = 4 4 " # cos(2✓ 2') sin(2✓ 2') 13 , sin(2✓ 2') cos(2✓ 2') rotation matrix for angle 2✓ 2'
Exercise 19E 1 a
c 2 a b
Exercise 19F 1 a y = 3x
3 1 777 7 14 77777 7 3 7777 5 14 3 3 777 7 7 77777 7 1 7777 5 7
9x +3 2 x 1 e y = 9x + 3 f y = 3
1 b y=
d y = 3x 1 x 1 g y= 3 9x 2 a y=6 2 2 3x c y= " # 7 2 0 3 0 2 " # 3 0 4 0 6
x +1 2
c y=
x+2 3 7x 2 d y= 12 b y=
5 y = (x + 1)2 1 6 y = (x 1)2 3 x2 7 2 + y2 = 1 3 y 1
–3
2 666 2 " # 666 1 1 67 b 6666 666 1 3 4 4 7 2 3 2 666 2 666 5 1 777 666 7 666 666 3 67 2 77777 d 6666 666 777 666 4 664 1 775 4 0 3 7 (x, y) ! (x 2y, 2x 5y) (x, y) ! (y, x + y)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
✓ 1 ◆ 3 a ( 1, 1) b ,1 2 " # 4 3 4 1 1 5 (0, 0), ( 1, 2), (1, 1), (0, 1) 2 3 " # 666 1 77 666 k 0 07777 1 6 a A= b A = 666 k 777 0 1 4 5 0 1 " # " # 1 k 1 k 7 a A= b A 1= 0 1 0 1 " # 1 0 8 a 0 1 b Reflecting twice in the same axis will return any point (x, y) to its original position " # cos(2✓) sin(2✓) 9 a sin(2✓) cos(2✓) b Reflecting twice in the same line will return any point (x, y) to its original position
–2
0
–1
1
2
3
x
–1
Exercise 19G 1 a Area = 2 y 2 1 0 1
2
3
4
x
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 743 c Area = 1
y
y
4 1
3
0 1
–1
1
–2
x
1
Exercise 19H
d Area = 7
3 2 1 0
x 1
2
3
–1
2 a
" 0# " # x y = y0 x+4 " 0# " # x x 2 2 0 = y y+2 " 0# " # x y+1 3 a 0 = b y x 1 " 0# " # x x c 0 = d y y+2 " # cos ✓ sin ✓ 4 a A= sin ✓ cos ✓ " # 1 0 b B= 0 k " # cos ✓ sin ✓ c C= sin ✓ cos ✓ d CBA = 1
y
0
7 b x= 1 8 m > 2 or p m3 < 1 2 666 3 77 66661 ± 2 77777 777 9 6666 666 1 7777 40 ± 5 2 " # a b 10 a c d
y 4 3 2
"
1 0 1
2
3
b Original area = 3 a
4
x
1 5 ; Image area = 2 2
y 4
#
Technology-free questions
2 1 –1
"
cos2 ✓ + k sin2 ✓ cos ✓ sin ✓ k sin ✓ cos ✓ cos ✓ sin ✓ k sin ✓ cos ✓ sin2 ✓ + k cos2 ✓
cos2 ✓ cos ✓ sin ✓ cos ✓ sin ✓ sin2 ✓ " 0# " # x x+1 6 0 = y y 1 5
" 0# " # x y 1 = y0 x 1 " 0# " # x x 4 = y0 y
#
Chapter 19 review
3
–1
19H ! 19 review
0
–1
x 0
–1
2
Answers
b Area = 4
0 1
2
3
x
1 a (7, 4)
b
c Area = 5
"
2 1
1 2
#
y
b Original area = 1; Image area = 5 4 m = ±2 5 m = 1, 2 " # 1 k 6 a i det =1 0 1 " # cos ✓ sin ✓ ii det =1 sin ✓ cos ✓ " # cos(2✓) sin(2✓) iii det = 1 sin(2✓) cos(2✓) b i Dilation of factor k from the y-axis and 1 dilation of factor from the x-axis k ii Determinant of matrix is 1
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
3 2 1 0
1
2
d (x, y) !
2 x 5
3
x
–1
1 1 2 y, x + y 5 5 5
!
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers
19 review
744 Answers 2 a
"
d
"
1 0 1 0
0 1 0 0
#
# " 1 0 1 c 0 5 0 2p 3 666 3 1 777 " 666 777 66 2 6 p2 7777 f 0 e 66 666 1 1 3 7777 4 5 2 2
b
#
2 666 666 6 3 a 6666 666 4 " 4 a 5 a b
6 a 7 a
"
3 4 3 777 7 ✓ 4 22 ◆ 5 5 77777 , 777 b 3 4 77 5 5 5 5 5 # " # " 0 1 0 1 0 b c 1 0 2 0 1 (x, y) ! (x 3, y + 4) (x, y) ! (x 3, y 4) " # " 1 0 1 A= bA 1= k 1 k Area of image = 3 square units
3 1 1 0
#
1 2
#
#
#
0 1
Extended-response questions 2 3 3 2p 1 7 666 1 666 3 1 777 666 p 666 777 p 77777 6 666 2 2 777 p2 7777 1 a 6666 2 b 7 6 666 1 666 1 1 777 3 7777 64 4p 5 p 75 2 2 2 2 c Product of these two matrices: p 3 p 2 3 1 + 3 777 6666 1 + 77 p p 666 2 2 p 2 7777 666 2 p 7 666 1 + 3 1 + 3 7777 64 p p 5 2 2 2p 2 p p 1+ 3 2+ 6 = d cos 75 = p 4 2 2 p p p 1+ 3 2+ 6 sin 75 = p = 4 2 2 2 a
y 6
y
5
1
4
0
1
2
3
3
x
2 1
–1
0
b Area of image = 5 square units
0
1
1
2
3
x
2
b Original area = 2 square units; Image area = 6 square units c 8⇡ " cubic # units 1 1 3 a 0 1 b Shear of factor 1 parallel to the x-axis c (0, 0), (2, 1), (0, 1) y d
y
0
1
x
–1 –2
" 0# " # x y 8 a 0 = y x 2 c
(–1, 1)
(2, 1)
1
2
x
p p p p 4 a (0, 2), ( 2, 0), (0, 2), ( 2, 0) 0
1
b
x
y (0, √2) 1
(1, –1) (–√2, 0)
–2
–1
Multiple-choice questions 1 B 2D 3 A 6 A 7D 8 E
4D 9D
5 C
0
(√2, 0) 0
1
x
–1 (0, –√2)
c 13 Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
0
–1
1
–1
(1, 1)
0
y
–1
1
b (1, 0)
p 8 2 square units
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Answers 745
Answers
2 a = 5, b = 1 3 a = 3, b = 15 " # " # " # " # " # 1 2 1 2 1 4 a b c d e 2 2 3 3 3 " # " # " # 2 5 4 5 a i ii iii 1 0 2 b a+b= c 6 a b y y 2
2
x
0
4
20A
5 b i The composition of two rotations is a rotation ii The composition of two reflections is a rotation iii The composition of a reflection followed by a rotation is a reflection iv The composition of a rotation followed by a reflection is a reflection p 3 2 666 1 3 777 7 6666 2 2 77777 c 6666 p 7 666 3 1 7777 4 5 2 2 2 3 666 3 4 777 666 7 p 65 5 77777 0 6 a 6666 7 b A ( 1, 3) c 2 10 666 4 3 7777 4 5 5 5 p d Isosceles f 2 10 7 a y
x
0 -3
−3
c
d
y 1
0
4
y 1
0
x
x
(a, b)
(0, b)
−4
-4 (0, 0)
(a, 0)
x
e
b O(0, 0), A(a cos ✓, a sin ✓), B( b sin ✓, b cos ✓), C(a cos ✓ b sin ✓, a sin ✓ + b cos ✓) ✓ 1 m2 2m ◆ 1 x 8 a y= ; (1, 0), , m m 1 + m2 1 + m2 ✓ x 2m m2 1 ◆ b y=1 ; (0, 1), , m 1 + m2 1 + m2 2 3 666 1 m2 2m 77 6666 1 + m2 1 + m2 77777 777 c 6666 m2 1 7777 6664 2m 5 1 + m2 1 + m2
Chapter 20
b 5
}
c
1
0
4
x
−4
7 a
b
y
y 4
1 0
x
2
0
c
Exercise 20A 1 a
y
d
y 4 3
1
y 4 3
2 2
x
3
0
1
e
x
3
0
f
y
2
4
x
y
1
d
2 0
3
−2 4
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
−1
5
−1
0
x 3
x −3
8 a and c
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Answers
20B ! 20D
746 Answers 9 ab
d Parallelogram
y
A
4 3 2 1
−1 −1
B C 0
2 1
3 4
x
D
10 m = 11, n = 7 1 11 a i b a ii b 2 ! ! b MN = AD ! ! 1 12 a CB = a b, MN = (b a) 2 ! ! b CB = 2 MN 13 a a b b c 2a e a f b a g a+b 14 a a b b c d a b e b a 1 15 a a b b (b a) c 3 1 1 d (a + 2b) e (4a b) 9 9 16 a u + v b v+w c 1 ! ! 17 a OB = u + v, OM = u + v 2 2✓ 1 ◆ c u v 3 2 2 ! ! 2 d OP = (u + v) = OB 3 3
d 2b a+b 1 (a + 2b) 3
u+v+w 1 bu v 2
e 2:1
Exercise 20B 1 2 3 4 5 6
7 8
9 10 11 12
2i 7 j a 5i + 6 j b 5i + 6 j c 5i 6 j a 5 b2 c 5 d 13 a 13 b x = 2, y = 7 5 7i + j 2 ◆ 2 2 1✓ 2 a i i ii i + j iii i+ j 5 5 6 5 1 1 iv i + j v 2i + j 3 6 ! 1 ! b i ON = OA ii 1 : 5 6 p 4 2 units 3 a k= , `=1 b x = 6, y = 2 2 1 5 c x = 3, y = 3 d k= , `= 3 3 p 3i 2 j, 13 a 2i + 4 j b 6i + j c 5 ✓3 3◆ a D( 6, 3) b F(4, 3) cG , 2 2 A( 1, 4), B( 2, 2), C(0, 10)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
13 a i 2i j ii 5i + 4 j iii i + 7 j iv 6i + 3 j v 6i + 3 j b D(8, 2) ! ! 14 a OP = 12i + 5 j, PQ = 6i + 8 j b 13, 10 p p p 15 a p i 29 p ii 116 iii 145 p b ( 29)2 + ( 116)2 = ( 145)2 16 a i pi 3 j ii 4ip+ 2 j iii p3i + j b i 10 ii 2 5 iii 10 17 a i 3i + 2 j ii 7 j 1 iii 3i 5 j iv ( 3i 5 j) 2 ✓ 3 9◆ b M , 2 2 1 1 18 a (3i + 4 j) b p (3i j) 5 10 1 1 c p ( i + j) d p (i j) 2 2 ✓ ◆ 6 1 1 1 e p i+ j f p (3i 2 j) 3 13 2 13
Exercise 20C 1 a 17 b 13 c e 4 f 3 g 2 a 5 b 13 c 8 p 3 a 15 2 b 4 a |a|2 + 4|b|2 + 4a · b b c |a|2 |b|2 d p 5 a 3i + j b 10 p 6 66 11 10 7 a b c 1 2 3 22 8 a a + qb b 29 9 a 139.40 b 71.57 c 3 11 a i b 45 c 2 3 1 12 a i i + 2 j ii i + 3 j 2 2
d 10 58 d 5 e 13 p 15 2 4a · b |a| c 116.57 8
p 2 ± 76 d 6 ✓ 44 110 ◆ c , 29 29 26.57 d 126.87 116.57 b 27.41
c 55.30
Exercise 20D 1 1 1 1 a p (i + 3 j) b p (i + j) c p (i j) 10 2 2 p 1 2 a i (3i + 4 j) ii 2 p5 2 b (3i + 4 j) 5 1 1 3 a i (3i + 4 j) ii (5i + 12 j) 5 13 1 b p (4i + 7 j) 65 11 13 4 a (i 4 j) b (i 4 j) c 4i 17 17
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Answers 747
6 a b c 7 a 8 a
b
Exercise 20E 4 1 1 1 p ii p iii p iv (q p) v q 5 5 5 5 RS and OQ are parallel ORS Q is a trapezium 120 cm2 1 2 k 6 i a + b ii a + b 3 3 7 7 7 i 3 ii 2 9 ! ! 15 i OD = 2i 0.5 j, OE = i+ j 4 4 p 170 ii 4 ✓ 15 9 ◆ i p i+ j 4 4 ii (q + 2)i + (4q 0.5) j 2 1 p= , q= 3 2 ! ! ! i AC = c ii OB = a + c iii AC = c a 2 2 |c| |a| 1 r+ t b (s + t) 2
1 ai b c d 2 a b 3 a
b c 5 a b 6 a
Exercise 20F
p i + 2 j k b 3i 5 j + 6k c 14 p 3 2 e 5i + 6 j k 2 j + 2k b i + 2j c i + 2k i + 2 j + 2k e 2 j f 2 j + 2k i + 2 j 2k h i 2 j 2k 3 1 1 a i p i+ p j p k 11 11 11 6 2 2 ii p i p j + p k 11 11 11 15 5 5 b p i+ p j p k 11 11 11 p 14 p (i j + 5k) 3 3 p 3 1 a i 3 j b 10 c i+ j k 2 2 1 17 a i + 2 j + 2k b 6 6
1 a d 2 a d g 3
4 5 6
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
Technology-free questions 12 1 a b ±9 7 2 A(2, 1), B(5, 3), C(3, 8), D(0, 4) 1 11 3 p= , q= 6 12 p 1 4 a 3 10 b p (i 5 j + 8k) 3 10 5 6 1 16 6 a (4i + 3 j) b (4i + 3 j) 5 25 1 7 a i a+b ii (a + b) iii b a 3 1 2 iv (2a b) v (2a b) 3 3 ! ! b T R = 2PT , so P, T and R are collinear 8 a p s = 2, t = 5, u = 2 b 33 p 9 109 units p 10 a 11i 2 j + 3k b 30 1 c p (5i + 2 j + k) d 2i + 4 j 30 11 a ( 1, 10) b h = 3, k = 2 12 m = 2, n = 1 2 3 13 a b = a + c b b= a+ c 5 5 14 a 13 b 10 c 8 d 11 e 9 f 0 g 27 6 3 7 16 a b ±p c 5 3 2 ! ! 17 a i AB = i ii AC = 5 j b 0 c 1 Multiple-choice questions 1 C 2 C 3E 6 B 7 A 8C
4 A 9 D
20E ! 20 review
9 a
Chapter 20 review
Answers
p p 1 2 3 1 4 5 b p c p d p 7 17 5 a = u + w where u = 2i and w = j a = u + w where u = 2i + 2 j and w = i j a = u + w where u = 0 and w = i + j 1 2i + 2 j b p ( i + j) 2 p 3 5 5 2 (i j) b (i + j) c 2 2 2 i i j ii i 5 jp 3 104 (i 5 j) c d2 13 13
5 a 2
5B 10 C
Extended-response questions " # " # 31 15 1 a b c |OR| = 25 32 20 p p p 2 a 34 b 10 20 c r = i 1 3 a b x = 2, y = 2 2 c p = 4, q = 2, r = 2 " # " # 7 20 4 a (25, 7), b 24 15 " # k 12 5 a (12, 4) b 4 p p 40 c 160, k, (k 12)2 + 16, k = 3 d 34.7
9j
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Answers
21 revision
748 Answers
Chapter 21 Technology-free questions 1 a All defined except AB h b DA = 6 "
i
12 ,
# 4 24
2 2 a 18 3 8 "
t
4 A=
3t " 5 AB =
#
5 9 15
6 a (7, 8) c area = 3
y
11 a area = 3 2
2 666 1 6666 9 A 1 = 6666 666 2 4 9 " 10 b 7
3 4 777 7 9 77777 7 1 7777 5 9 # 19 16
1 0
#
8 , 10 " 2 b 1
C 1 2
1
#
2 666 2 6 = 66666 3 4 2
1
2
3
0
1
2
3
x
–1 –2 y
b area = 5 ,t2R
0
2
3 1 777 7 1 77777 5 2
1 0
x
–1
y
–2
" 0# " # x y+1 12 a 0 = y x 1 y c
1 0 0
1
2
3
4
x
–1
b (0, 0) ! (1, 1)
2
–2 1 –3
d 7 a
d
f
8 a
9 a 10 a b
1 1 2 ◆ (x, y) ! x + y, x y 3 3 3 3 " # " # 1 0 3 0 b c 0 1 0 1 p 3 2p 2 777 6666 2 " # 777 666 2 0 0 2 6 p 7777 e 666 p 666 2 0 1 2 7777 4 5 2 2 2p 3 666 3 1 777 " # 666 777 1 666 2 p2 7777 g 0 h 666 1 0 3 7777 664 1 5 2 2 3 2 8 777 6666 15 666 17 17 7777 666 777 b 666 8 15 7777 64 5 17 17 " # " # 1 0 1 0 b c 0 2 0 1 (x, y) ! ( x + 2, y 1) (x, y) ! ( x 2, y 1)
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
✓2
0
x 0
"
1 2
0 1
#
2
–1
–2
2 666 1 666 666 p2 666 664 3 2
p 3 3 777 7 2 77777 7 1 7777 5 2
"
1 0
✓ 2 76 ◆ , 17 17 2 1
1
#
13 a 13 e 5
b 13 f 0
46 , n= 11 c p = 3, 5
14 a m =
c 13 g 13 18 11
d
13
b p = 48
Multiple-choice questions 1 A 2 B 3E 6 C 7 A 8B 11 C 12 B 13 A 16 C 17 D 18 D 21 B 22 B 23 B 26 A 27 B 28 D 31 C 32 B 33 B
4 9 14 19 24 29
5 10 15 20 25 30
A D E E D A
Extended-response questions " 2 # " a + bc ab + bd 3a 1 a i ii 2 ac + dc d + bc 3c
3b 3d
B D B D B B
#
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Answers 749
b
" 0# " # x x+6 = y0 y+3
6 a
y 5
c
4 3 2
e
1 1
2
x
–2
7 a
–3 –4
y = 2x
–5
c
21 revision
–4 –3 –2 –1 –1
p 3 p 3 2p 2 p 666 2 666 2 2 777 2 777 666 777 666 777 666 p2 7 6 2 2 2 7 6 p 77 p p 7777 6 b 666 6 666 2 2 7777 2 7777 664 2 64 5 5 2 2 2p 2 p p 3 2 2 a = 2, b = 0 d c= , d= 2 p 2 p 3 2 6 7 " # 6666 2 x0 + 2 y0 7777 777 x 66 2 2 p 77 i = 6666 p 666 2 0 y 2 0 7777 4 x + y5 2 2 p ii 2(y x) = (x + y)2 ⇡ b a = 2, b = y 4
Answers
2 a
y=x
y
x 6 4 2 0 –8 –7 –6 –5 –4 –3 –2 –1
d y = 2(x + 3)2 + 2
e
x
" 0# " # x x+3 = y0 2y + 4
3 a (4, 1) b i Rectangle with vertices A0 (0, 0), B0 (0, 1), C 0 (4, 1), E 0 (4, 0) ii 1 iii 4 iv k " 0# " # x 4x c 0 = y y 1 2 1 d i y= x ii y = (x 2)2 1 16 16 iii y
2 3 1 7 666 3 666 p p 77777 6 10 777 c 6666 10 7 666 1 3 7777 4p p 5 10 10 8 a i (3, 1) ii A0 (3, 1), B0 (5, 1), C 0 (3, 3) iii y 5 4 3 2 1 –5 –4 –3 –2 –1 0 1 2 3 4 5 –1
x
–2 –3 –4 –5
(0, 0) (2, 0)
(6, 0)
" 0 # 26 x + 2 37 66 777 x 77 e 0 = 66664 1 y (y + 3)75 5 4 b i x2 + (y 1)2 = 1 ✓ 4 ◆2 ✓ 3 ◆2 ii x + + y =1 5 5 ✓4 8◆ c (0, 0), , 5 5 " 1 3 5 a ( 3, 11) b 10 2 c a = 2, b = 3 d (5a, 5a) e = 2, b = 2a; = 5, b = a
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
x
(2, –1)
# 1 4
b ii ( 1, 1), (2, 2) iv ( 1, 1), (2, 2), ✓1 p 1 p ◆ ( 1 + 5), ( 1 5) , 2 2 ✓1 p 1 p ◆ ( 1 5), ( 1 + 5) 2 2 1 ! 9 a AE = (2a + tb) t+1 9 ! ! 1 b AE = (7a + AF) d t = 8 7 10 b (n 1)a nb + c 3 1 ! ! 11 a AB = b a, PQ = a+ b 10 2 ✓ 3 ✓ 1 ◆ 1◆ 1 bi n a + b ii k + b a 10 2 2 2 5 1 c n= , k= 3 3
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Answers
22A ! 22D
750 Answers p 12 a p 4 2 km/h blowing from the south-west b 5 km/h; 200 m downstream c 43.1 km/h at bearing 80 d 222 ! 1 ! 1 ! 13 b ii ZG = h ZH + k ZK 3 3 1 1 2 iii + = 3 iv h = ; similarity h k 3 4 v cm2 9 1 vi h = ; H is midpoint of ZX, K = Y 2 vii h 1
1 ≤ k ≤ 1; 2 1 2 ≤h≤1
1 2 1 2
viii
k
1
A 2 4 , 3 9
1 1 2 1 2
1
k
2 s and a = 2 cm/s2 ; 3 when t = 1 and a = 2 cm/s2 5 b When t = s and the particle is moving to 6 1 the left at cm/s 6 5 When t = 2 s, v = 6 cm/s, a = 14 cm/s2 ; when t = 3 s, v = 5 cm/s, a = 8 cm/s2 ; when t = 8 s, v = 30 cm/s, a = 22 cm/s2 3 6 a t = 4 s and t = 1 s b t = s 2 4 a When t =
Exercise 22B 1 a x = 2t2 6t b At the origin O c 9 cm d 0 cm/s e 3 cm/s 2 a x = t3 4t2 + 5t + 4, a = 6t 8 5 b When t = 1, x = 6; when t = , x = 5 23 27 3 c When t = 1, a = 2 m/s2 ; 5 when t = , a = 2 m/s2 3 3 20 m to the left of O 4 x = 215 13 m, v = 73 m/s 5 a v = 10t + 25 b x = 5t2 + 25t c 2.5 s d 31 14 m e 5 s 6 29th floor
Exercise 22C p 1 2 10 s 2 37.5 m
Chapter 22 Exercise 22A 1 a b c d e f 2 a d 3 a b c d e f g
3 a 3 m/s2
12 cm to the right of O 2 cm to the right of O Moving to the left at 7 cm/s When t = 3.5 s and the particle is 0.25 cm to the left of O 2 cm/s 2.9 cm/s After 3.5 s b 2 m/s2 c 14.5 m When t = 2.5 s and the particle is 1.25 m to the left of O 3 cm to the left of O moving to the right at 24 cm/s v = 3t2 22t + 24 4 After s and 6 s 3 11 22 cm to the right of O and 39 cm to the 27 left of O 4 23 s a = 6t 22 11 When t = s and the particle is 13 16 cm 27 3 1 left of O moving to the left at 16 3 cm/s
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
4 5 6 7 8 9 10
a a a a a a a
b 6 23 s
2.5 m/s2 50 s 20 s 19.2 m/s 59.2 m/s 10 s 4.9(1 2t) m/s
c 337.5 m d b b b b b b b
500 s 27
31.25 m 625 m 10 m/s 1.6 m 158.4 m after 3 s and 7 s 4.9t(1 t) + 3 m 10 c 4.225 m d s 7 11 a 2 s b 44.1 m c 4 s d 5s p 12 10 10 m/s
Exercise 22D 1 65 m 2 a 562.5 m 200 3 m/s 3 4 210 m 5 a 500 m 6 a 12.5 s
b 450 m
c 23.75 s
b 375 m b 187.5 m
c 17.57 s
Cambridge University Press ISBN 978-1-107-56765-8 © Evans et al. 2016 Photocopying is restricted under law and this material must not be transferred to another party.
Answers 751 1 1 1 b x= t3 2 2t 9 a a = 3t2 22t + 24 b 15 m/s2 1 7 c 2 12 m to the left, 60 12 m 10 40 m 8 a a=
20
0
10
t
14
a 41 23 s a 7.143 s a 2s 437.5 m a 288 m 16 m/s 80 18 m/s2 81 19 a 0 m/s 12 13 14 15 16 17
9 a
20 a 2t
0
5
17
20
t
10 m/s2 3 10 No, the first train will stop after 6.25 km and the second train will stop after 6 km. 11 a 57.6 km/h b 1 minute 6 23 seconds c 0.24 b
Chapter 22 review Technology-free questions 1 a 5 cm to the left of O b 8 cm to the left of O c 4 cm/s d t = 2 s, 9 cm to the left of O e 1 cm/s f 1 23 cm/s 2 a 8 cm to the right, 0 cm/s, 4 cm/s2 b At t = 0 s, 8 cm to the right, 4 cm/s2 ; 4 at t = s, 6 22 cm to the right, 4 cm/s2 27 3 3 a 3.5 s, 40.5 cm/s, 36 cm/s2 b 2s c 31 cm 1 4 a i cm to the left ii 1 cm/s2 iii 1 cm/s 8 32 b i 0 s, 2 s ii cm 27 3 5 a 12 m/s b x = t 6 a 4s b 18 23 m to the right c 5 m/s2 d 1.5 s e 6 14 m/s 1 7 a m to the left b 1 m/s c 5 m/s2 12
Cambridge Senior Maths AC/VCE Specialist Mathematics 1&2
b 347 29 m b 2 67 s, 4 27 s b 39.6 m c 4 s
21 22 23 24
3 m/s2 11 e m 12
b
t2 + 8
b i 8 m/s a 27 m/s2 a 10 m/s a 4 s, 6 s
d
100 s 9
d 4.84 s
b 16 s
d 4 32 m
10
c 500 m
ii b b b
b t2
c
22 review
b From initial position O, the particle moves to the right with initial velocity 20 m/s. It slows until after 10 seconds it is 100 m from O and momentarily stops. It then moves to the left towards O, getting faster. c 116 m d 84 m to the right of initial position 8 a 1 m/s2 b 2.5 m/s2 c 215 m d 125 m to the right of initial position
11 a 2.5 m/s2 b 8 s
Answers
7 a
4 m/s
t3 + 8t 3
2 s iii 18 m 50 m/s c 4.5 s 0m 36 m c 0t